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Monday 26 May 2014

NEWS LETER

1. Rita Onyemachi emerges Most Beautiful Face In Nigeria 2014. 2. Angry fan slams Jay Z and Beyonce for not attending Kanye.s wedding. More at www.360nobs.com

Friday 2 May 2014

THE ATMOSPHERE

Atmosphere

Atmosphere, mixture of gases surrounding any celestial object that has a gravitational field strong enough to prevent the gases from escaping; especially the gaseous envelope of Earth. The principal constituents of the atmosphere of Earth are nitrogen (78 percent) and oxygen (21 percent). The atmospheric gases in the remaining 1 percent are argon (0.9 percent), carbon dioxide (0.03 percent), varying amounts of water vapor, and trace amounts of hydrogen, ozone, methane, carbon monoxide, helium, neon, krypton, and xenon.

The mixture of gases in the air today has had 4.5 billion years in which to evolve. The earliest atmosphere must have consisted of volcanic emanations alone. Gases that erupt from volcanoes today, however, are mostly a mixture of water vapor, carbon dioxide, sulfur dioxide, and nitrogen, with almost no oxygen. If this is the same mixture that existed in the early atmosphere, then various processes would have had to operate to produce the mixture we have today. One of these processes was condensation. As it cooled, much of the volcanic water vapor condensed to fill the earliest oceans. Chemical reactions would also have occurred. Some carbon dioxide would have reacted with the rocks of Earth’s crust to form carbonate minerals, and some would have become dissolved in the new oceans. Later, as primitive life capable of photosynthesis evolved in the oceans, new marine organisms began producing oxygen. Almost all the free oxygen in the air today is believed to have formed by photosynthetic combination of carbon dioxide with water. About 570 million years ago, the oxygen content of the atmosphere and oceans became high enough to permit marine life capable of respiration. Later, some 400 million years ago, the atmosphere contained enough oxygen for the evolution of air-breathing land animals.

The water-vapor content of the air varies considerably, depending on the temperature and relative humidity. With 100 percent relative humidity, the water-vapor content of air varies from 190 parts per million (ppm) at -40°C (-40°F) to 42,000 ppm at 30°C (86°F). Minute quantities of other gases, such as ammonia, hydrogen sulfide, and oxides of sulfur and nitrogen, are temporary constituents of the atmosphere in the vicinity of volcanoes and are washed out of the air by rain or snow. Oxides and other pollutants added to the atmosphere by industrial plants and motor vehicles have become a major concern, however, because of their damaging effects in the form of acid rain. In addition, the strong possibility exists that the steady increase in atmospheric carbon dioxide, mainly as the result of the burning of fossil fuels since the mid-1800s, may affect Earth’s climate (see Greenhouse Effect).

Similar concerns are posed by the sharp increase in atmospheric methane. Methane levels have risen 11 percent since 1978. About 80 percent of the gas is produced by decomposition in rice paddies, swamps, and the intestines of grazing animals, and by tropical termites. Human activities that tend to accelerate these processes include raising more livestock and growing more rice. Besides adding to the greenhouse effect, methane reduces the volume of atmospheric hydroxyl ions, thereby curtailing the atmosphere’s ability to cleanse itself of pollutants. See also Air Pollution; Climate; Smog.

The study of air samples shows that up to at least 88 km (55 mi) above sea level the composition of the atmosphere is substantially the same as at ground level; the continuous stirring produced by atmospheric currents counteracts the tendency of the heavier gases to settle below the lighter ones. In the lower atmosphere, ozone, a form of oxygen with three atoms in each molecule, is normally present in extremely low concentrations. The layer of atmosphere from 19 to 48 km (12 to 30 mi) up contains more ozone, produced by the action of ultraviolet radiation from the sun. Even in this layer, however, the percentage of ozone is only 0.001 by volume. Atmospheric disturbances and downdrafts carry varying amounts of this ozone to the surface of Earth. Human activity adds to ozone in the lower atmosphere, where it becomes a pollutant that can cause extensive crop damage.

The ozone layer became a subject of concern in the early 1970s, when it was found that chemicals known as chlorofluorocarbons (CFCs), or chlorofluoromethanes, were rising into the atmosphere in large quantities because of their use as refrigerants and as propellants in aerosol dispensers. The concern centered on the possibility that these compounds, through the action of sunlight, could chemically attack and destroy stratospheric ozone, which protects Earth’s surface from excessive ultraviolet radiation. As a result, industries in the United States, Europe, and Japan replaced chlorofluorocarbons in all but essential uses. See Aerosol Dispenser; Ozone Layer; Photochemistry.

The atmosphere may be divided into several layers. In the lowest one, the troposphere, the temperature as a rule decreases upward at the rate of 5.5°C per 1,000 m (3°F per 3,000 ft). This is the layer in which most clouds occur (see Cloud). The troposphere extends up to about 16 km (about 10 mi) in tropical regions (to a temperature of about -79°C, or about -110°F) and to about 9.7 km (about 6 mi) in temperate latitudes (to a temperature of about -51°C, or about -60°F). Above the troposphere is the stratosphere. In the lower stratosphere the temperature is practically constant or increases slightly with altitude, especially over tropical regions. Within the ozone layer the temperature rises more rapidly, and the temperature at the upper boundary of the stratosphere, almost 50 km (about 30 mi) above sea level, is about the same as the temperature at the surface of Earth. The layer from 50 to 90 km (30 to 55 mi), called the mesosphere, is characterized by a marked decrease in temperature as the altitude increases.

From investigations of the propagation and reflection of radio waves, it is known that beginning at an altitude of 60 km (40 mi), ultraviolet radiation, X rays (see X Ray), and showers of electrons from the sun ionize several layers of the atmosphere, causing them to conduct electricity; these layers reflect radio waves of certain frequencies back to Earth. Because of the relatively high concentration of ions in the air above 60 km (40 mi), this layer, extending to an altitude of about 1000 km (600 mi), is called the ionosphere. At an altitude of about 90 km (55 mi), temperatures begin to rise. The layer that begins at this altitude is called the thermosphere, because of the high temperatures reached in this layer (about 1200°C, or about 2200°F). The region beyond the thermosphere is called the exosphere, which extends to about 9,600 km (about 6,000 mi), the outer limit of the atmosphere.

The density of dry air at sea level is about 1/800 the density of water; at higher altitudes it decreases rapidly, being proportional to the pressure and inversely proportional to the temperature. Pressure is measured by a barometer and is expressed in millibars, which are related to the height of a column of mercury that the air pressure will support; 1 millibar equals 0.75 mm (0.03 in) of mercury. Normal atmospheric pressure at sea level is 1,013 millibars, that is, 760 mm (29.92 in) of mercury. At an altitude of 5.6 km (about 3.5 mi) pressure falls to about 507 millibars (about 380 mm/14.96 in of mercury); half of all the air in the atmosphere lies below this level. The pressure is approximately halved for each additional increase of 5.6 km in altitude. At 80 km (50 mi) the pressure is 0.009 millibars (0.0069 mm/0.00027 in of mercury).

The troposphere and most of the stratosphere can be explored directly by means of sounding balloons (see Ballooning) equipped with instruments to measure the pressure and temperature of the air and with a radio transmitter to send the data to a receiving station at the ground. Rockets carrying radios that transmit meteorological-instrument readings have explored the atmosphere to altitudes above 400 km (250 mi). Study of the form and spectrum of the polar lights (see Aurora) gives information to a height possibly as great as 800 km (500 mi). See Space Exploration.

For circulation of the atmosphere, see Meteorology; Wind.

Wednesday 30 April 2014

Dog

INTRODUCTION

Domestic Dogs

The domestic dog, Canis lupus familiaris, believed to be a direct descendant of the wolf, Canis lupus, has been selectively bred into hundreds of different breeds.

Dog, mammal generally considered to be the first domesticated animal. This trusted work partner and beloved pet learned to live with humans more than 14,000 years ago. A direct descendant of the wolves that once roamed Europe, Asia, and North America, the domestic dog belongs to the dog family, which includes wolves, coyotes, foxes, and jackals. Dog ancestry has been traced to small, civet-like mammals, called miacis, which had short legs and a long body and lived approximately 40 million years ago.

The evolving relationship between the domestic dog and humans has been documented in fossil evidence, artifacts, and records left by earlier civilizations. Prehistoric dog skeletal remains, excavated from sites in Denmark, England, Germany, Japan, and China, indicate the early coexistence of dogs with people. An ancient Persian cemetery, dating to the 5th century bc, contained thousands of dog skeletons. Their formal burial and the positioning of the dog remains reveal the esteem in which the ancient Persians held their dogs. The relationship shared by dogs and humans also is evident in cave drawings, early pottery, and Asian ivory carvings that depict dogs. A statue of Anubis, the half dog, half jackal Egyptian god, was discovered inside King Tutankhamen’s tomb, constructed in about 1330 bc.

Literary references to the dog include those found in the Bible and in the Greek classic the Odyssey by Homer. In 1576 an English physician and dog fancier, John Caius, wrote a detailed text on dog breeds, Of English Dogges. Dogs are featured in tapestries that were created in the Middle Ages (5th century to 15th century), and in the work of many artists, including 17th- and 18th-century European painters Peter Paul Rubens and Thomas Gainsborough.

Although it is not known how humans and dogs first learned to coexist, people soon discovered the many ways dogs could enrich their lives. Dogs have been used to hunt for food, herd animals, guard livestock and property, destroy rats and other vermin, pull carts and sleds, perform rescues, and apprehend lawbreakers. They have been used during wartime as sentinels and message carriers. Today trained dogs are used to alert deaf people to common household sounds, such as the ringing telephone or doorbell; guide the blind; or retrieve objects for quadriplegics. Perhaps the most common of the many roles served by the domestic dog, however, is that of companion. As animals with strong social tendencies, dogs typically crave close contact with their owners. And people tend to form loving bonds with dogs. This companionship often helps to ease the pain and isolation of the elderly or people whose physical or mental health requires long-term convalescence or institutionalization.

PHYSICAL CHARACTERISTICS

Dog Skeleton

A dog’s skeleton enhances agility and endurance. The strong front legs bear more than 60 percent of the animal’s weight, yet still permit flexibility and nimbleness. The hind legs, attached to massive muscles, enable powerful acceleration and help to maintain running speed.

Domestic dogs vary widely in appearance, particularly in size. The Shih Tzu, for example, is 20 to 28 cm (8 to 11 in) in length and weighs 4 to 7 kg (9 to 15 lb). The Irish wolfhound is at the other end of the scale, measuring about 71 to 94 cm (about 28 to 37 in) at the shoulder and weighing up to about 61 kg (about 135 lb). Coat color, length, texture, and pattern also vary greatly. The muzzle may appear shortened, as in the Pekingese, or elongated, as in the Doberman pinscher. Limbs are relatively short in the basset hound and dachshund, but long in the greyhound. Ear shape and carriage also vary, but these characteristics may be influenced by a dog owner’s decision to crop, or cut, the ears to make them stand up. Some dogs, notably the chow chow, even have a naturally blue-black tongue.

Despite these differences, all breeds of the domestic dog are essentially identical in anatomy. The skeleton of the domestic dog has an average of 321 bones, with variation reflecting differences in the number of bones in the tail and the presence of a dewclaw, an extra digit on the paw that not all breeds have. The rib cage consists of 13 pairs of ribs; the spine has 7 cervical vertebrae, 13 thoracic vertebrae, 7 lumbar vertebrae, and 3 sacral vertebrae. Rear paws have four complete digits and front paws have four or five digits. Most puppies have 28 temporary teeth, which are replaced with 42 permanent teeth at about six months of age.

Some breed differences evolved to help dogs survive in their native environment or occupation. For example, dogs that lived and worked outdoors, such as the Komondor of Hungary, needed a thick, weather-resistant coat to protect them from the elements and, perhaps, the biting teeth of predatory animals. Similarly, the Labrador retriever developed an oily coat, webbed feet, and a rudder-like tail to help it perform better in recovering downed waterfowl.

Just as distinct physical characteristics became trademarks in some breeds, unusual sensory abilities characterize others. Most dogs are able to detect scents and hear high-pitched sounds that are beyond human perception, but some breeds have especially acute sensory skills. The bloodhound, for instance, can follow a four-day-old track using its highly developed sense of smell. Other breeds with a keen sense of smell include the German shepherd, golden retriever, beagle, and Newfoundland. These dogs have been trained for such varied duties as detecting hidden drugs, explosives, termites, and even a decomposing body immersed in deep water.

III

REPRODUCTION, BIRTH, AND THE YOUNG

Mother Dog with Puppies

Domestic dogs commonly have litters with three to six puppies. The puppies are born blind and helpless. They depend on their mother's milk for three to four weeks, after which they may begin to eat some solid food. Puppies are usually weaned completely at about six weeks.

Stan Fellerman/Corbis

Dogs generally reach sexual maturity at about six months of age, with small breeds often maturing earlier than large breeds. Female dogs, or bitches, become sexually receptive to mating during a period called estrus (also called season or heat), which occurs about twice a year for 6 to 12 days. After a gestation period of about 63 days, an average litter of three to six puppies is born.

Blind and unable to stand, newborn puppies are helpless and spend 90 percent of their time sleeping and 10 percent nursing. Becoming chilled is the greatest danger facing a healthy newborn puppy because its immature circulatory system cannot sustain an adequate body temperature. For this reason, newborn puppies tend to stay close to their mother or cuddle together for warmth. Mothers clean, nurse, and defend their pups until they can live on their own, but fathers do not involve themselves in the care of the young.

DOG BREEDS

Cairn Terrier

Cairn terriers originated on the Isle of Skye, off the coast of Scotland. Skilled and courageous working dogs, old-world cairn terriers would bolt rodents and small mammals from cairns, or piles of rocks. Modern breeders of the dogs attempt to preserve the character of old-world cairn terriers.

Dorling Kindersley

Of the more than 300 breeds of dogs that exist worldwide, 150 are recognized by the American Kennel Club (AKC), the primary kennel club in the United States. Since its founding in 1884 the AKC registers purebred dogs—dogs whose parents and ancestors were of the same breed since the breed was first recognized. More than one million such dogs are registered annually. Kennel clubs in other countries, such as the Canadian Kennel Club, the Kennel Club of England, and the Japanese Kennel Club, use their own standards in recognizing dog breeds.

Norwegian Elkhound

The Norwegian elkhound is a breed of hunting dog. The breed is characterized by a short, strong body, a broad chest, a thick coat, and a curled tail.

Robert and Eunice Pearcy/Animals Animals

The AKC organizes the 150 breeds it recognizes into seven groups (plus a miscellaneous category), based on physical and temperamental characteristics and the purpose for which the breed was originally developed. The club classifies breeds as terrier, working, sporting, hound, herding, toy, and nonsporting.

Bulldog

The bulldog was originally bred for the sport of bullbaiting; after the sport was banned, the bulldog was bred once again to lose its viciousness. The bulldog is often considered a mascot of the British.

Dorling Kindersley

The terriers often have wiry coats and possess a feisty personality, which reflects their original use in catching prey such as foxes, badgers, and rabbits. Working dogs, such as the boxer or Alaskan Malamute, are muscular, even-tempered, and obedient, a necessary quality in dogs that serve as working partners with humans. Many of the sporting dogs, such as pointers and retrievers, are active dogs that respond instinctively when spotting game. Hounds such as the beagle are known for their stamina, acute sense of smell, and baying bark, qualities that are an invaluable aid to hunters and trackers. Other tireless helpers of humans are herding dogs, recognized for their innate ability to drive livestock and keep farm animals from straying. The low-to-the-ground Pembroke or Cardigan Welsh Corgi can drive a herd of cows many times its size. Toy dogs, on the other hand, are known for their diminutive size and function as companionable house pets. The papillon, named for the French word for butterfly because it has ears that resemble butterfly wings, is a happy, friendly dog, suitable for small living spaces. The final dog group, nonsporting , includes a wide variety of purebreds that differ in size, coat, overall appearance, and personality, from the shorthaired spotted dalmatian to the curly-haired poodle.

Kuvasz

The kuvasz is a breed of working dog originally bred as guard dogs in Europe. This large breed is characterized by strong muscles and a white coat.

Gerard Lacz/Peter Arnold, Inc.

Pug

A pug is a breed of toy dog characterized by a wrinkled forehead and flat, black nose. Its short hair can be solid black or light- colored with black markings on the face and ears.

Carolyn A. McKeone/Photo Researchers, Inc.

Groenendael Belgian Sheepdog

Its black color distinguishes the Groenendael variety of Belgian sheepdog from the three other varieties—the Belgian Laekenois, the Belgian Malinois, and the Belgian Tervuren. Although sheepdogs were first developed in the 1200s, the Groenendael breed, also known simply as the Belgian sheepdog, was not created until the late 1800s, when the owner of a café in Groenendael, Belgium, mated two black sheepdogs. The Belgian sheepdog is often used to herd and guard farm livestock.

Henry Ausloos/Animals Animals

Cocker Spaniel

The cocker spaniel has long been bred for hunting and may have been named after a primary prey, the woodcock. Hunters valued the dog for its intelligence and trainability. These qualities serve domestic pet owners as well, contributing to the breed’s popularity as a pet.

Dorling Kindersley

DOG BEHAVIOR

Instinctive behaviors of the domestic dog are comparable to those of its wild relatives, the wolf, coyote, fox, and jackal. Unlike trained behaviors, such as being housebroken or responding to human commands, instinctive behaviors are those that dogs do without being taught and include vocalizations, body language, and marking. For example, by four weeks of age, puppies bark, whine, growl, and howl—-just like their wild relatives. Even the African Basenji, known as the barkless dog, yodels when aroused. These sounds, whether elicited in excitement, fear, territoriality, or pain, are one way that dogs communicate with one another and with other animals and people.

Dogs also communicate through their use of body language. Facial expression, ear posture, tail carriage, hackle (hair on back) display, and body stance signal a dog’s state of fear, excitement, aggression, or submission. Understanding the meaning behind these signals can be important. Signs of potential hostility in a dog include bared teeth, flattened ears, erect tail, stiff legs, and bristling back hair; the dog may also growl or bark. People observing these behaviors should keep their arms at their sides and slowly back away, while firmly saying “no.” When approaching a strange dog, first ask the owner if the dog may be touched. Once given permission, hold the hands low and speak softly. Staring directly at a dog may arouse intimidation or aggression, so eye contact with strange dogs should be avoided.

Dogs typically mark their territory with urine as part of the social communication between animals in general and among the species. A dog may defend the territory by growling, barking, or assuming aggressive body language.

In addition to these instinctive behaviors, dogs are capable of learning certain trained behaviors, such as following obedience commands. The domesticated dog is able and willing to learn appropriate behaviors and is highly motivated to please its owner, critical factors that have contributed to the success of the domestic dog as a companion.

CARING FOR A DOG

The decision to adopt a dog should be made carefully because it is a serious commitment that can last for several years. Small dogs may live 12 or more years, although very large dogs typically have a shorter lifespan, sometimes as brief as 8 years. Before buying a dog, potential owners should examine their lifestyle, living accommodations, and plans for the dog. Other decisions should include who, in the case of a family, will care for the dog and whether the family or individual owner will have enough time, attention, and money to meet the dog’s needs.

For example, a busy family might not have the necessary time to groom a dog with a thick coat, and some people might be unwilling to keep up with the frequent vacuuming needed with a breed that sheds large amounts of hair. Further, a large dog that requires lots of exercise would not thrive in a small apartment, nor would a tiny dog be safe around very young children, who may be too rough with these dogs. Potential owners also should decide which gender dog they prefer and if it will be used for breeding. Another decision is to determine if the dog will be a show dog, a working dog, or a pet because this will influence which individual to select. Finally, anyone who would like to acquire a dog should be sure to budget for its food; medical expenses, which will cover immunizations, check-ups, and sick visits; and any kennel care required in the owner’s absence.

Many people prefer a purebred dog so that they can predict how the dog will look and act when fully grown. Most veterinarians and responsible dog fanciers believe that a private breeder with a good track record in producing healthy puppies is the best option for choosing purebreds. To locate a breeder, check the newspaper, visit a dog show, contact a veterinarian or experienced acquaintance, or call a local kennel club or the AKC. Visit several breeders and meet each litter’s dam (mother) and sire (father), if possible. Be prepared to ask, and answer, a lot of questions. Reputable breeders vigorously screen prospective buyers to ensure that their puppies go to good homes. Other potential owners are satisfied with mixed-breed dogs, called mongrels or mutts. Animal shelters and humane societies, veterinarian offices, and classified advertising are all resources for finding a mixed-breed that meets the needs of a potential owner.

When adopting a puppy, wait until it is at least eight weeks of age before separating it from its mother. Although the various breeds, and dogs in general, have different temperaments, look for a clean puppy that is happy, outgoing, and alert. A puppy that is excessively shy or thin or that has obvious health problems, such as discharge from its eyes or nose, is not a good choice.

A new puppy should be taken to a veterinarian soon after adoption for a thorough physical examination and to ensure that it is current on vaccinations. All puppies need a series of immunizations to protect them against distemper, a viral disease that causes respiratory symptoms and can affect the nervous system; leptospirosis, a bacterial disease that damages the liver; hepatitis, a viral disease that also targets the liver; parvovirus, which harms the intestinal tract; and parainfluenza, which causes respiratory problems. Immunizations for these five diseases are usually administered in one vaccination. Dogs also need rabies shots to protect them from this virus, which is transmitted in the saliva by the bite of an infected animal and attacks the nervous system. Some owners opt for additional vaccinations against Lyme disease, a bacterial infection that is transmitted by parasitic deer ticks; kennel cough, a respiratory disease caused by the bordatella bacteria; and coronavirus, which targets the intestinal tract.

Most young puppies harbor roundworms, intestinal parasites that are diagnosed by examining a stool sample. Roundworms rob the puppy of nutrients, resulting in the puppy’s failure to thrive; the parasites are eliminated with several doses of oral medication. Dogs of all ages should follow a drug regimen to protect them from another parasite, heartworm, which damages heart tissue, obstructs blood flow, and often causes death. The veterinarian should also discuss spaying or neutering (making a dog infertile), which are essential in nonbreeding dogs to protect their health and reduce the population of unwanted dogs. This common surgical procedure is usually not done until a pup is six months old.

Veterinarians recommend that dogs of all ages have a yearly checkup, including vaccination booster shots and screening for external and internal parasites. Since dogs cannot communicate their health problems through words, an annual examination is important for the early detection and treatment of problems. Owners should be aware of signs of possible illness requiring veterinary attention, including changes in appetite and behavior.

All puppies and dogs have three daily requirements: plenty of fresh drinking water, correct amounts of nutritious food, and adequate exercise for the dog’s age, breed, and temperament. An outdoor dog needs shelter from the elements and plenty of shade during the summer months, and indoor pets must have regular access to the outdoors for elimination. Whatever their living arrangements, all dogs require the loving attention of their owners.

Grooming considerations vary from breed to breed. Short-coated dogs usually need to be brushed once or twice a week, whereas long-haired dogs may need daily grooming to prevent the coat from matting or tangling. Dogs need only be bathed when dirty, and the shampoo used should be one that will protect the coat’s natural oils. Grooming also includes attending to the dog’s eyes, ears, teeth, anal glands, and nails; details of such care, however, should first be explained by a veterinarian.

VII

TRAINING YOUR DOG

Dogsledding

Dogs are often used to drive sleds, such as these sled dog teams in Canada’s Northwest Territories.

Corbis

Training is another vital part of raising a happy and healthy dog. All dogs should be trained to walk on a leash and be housebroken. Some people prefer housebreaking a puppy by training it to urinate and defecate on newspapers, which are laid flat in a small area such as a foyer. The puppy is rewarded each time it voids on the paper; then the newspapered area is gradually reduced and finally eliminated altogether. However, crate training, in which a dog is confined to a crate for limited periods, is more effective because dogs will avoid soiling their own living quarters. Whichever method is chosen, housebreaking should begin as soon as a puppy comes home with its new owner, who should provide the puppy with frequent opportunities to urinate and defecate outside. In general, pups are not completely housebroken until they are at least 12 weeks old.

Most puppies are ready to begin obedience lessons at six to eight months of age. The first lessons should be relatively brief, about 10 to 15 minutes a day, and gradually increase to 30 minutes, depending on the dog’s level of concentration. Training is best accomplished with lots of praise and a stern “no” for corrections. The trainer should always be consistent in reinforcing good behavior and correcting bad behavior and should never strike a dog. Many trainers use a leash and chain-link collar, known as a choke collar. Despite its name, the collar is never meant to choke a dog, but is used to deliver quick snaps to gain and direct a dog’s attention. This training collar is useful in teaching basic obedience commands, such as sit, stay, heel, come, and down.

VIII

DOG SHOWS

Poodle Clipping

A poodle submits to having its fur trimmed. The clipping of poodles originated as a method of reducing drag while the dog was swimming. Trimming is often a requirement for dogs that are entered in shows.

Jerry Cooke/Photo Researchers, Inc.

In the United States, the AKC sponsors 14,000 competitive dog shows and performance events each year. Dog show judges evaluate a dog’s conformation to its breed standard—an official physical description of the ideal specimen for a particular breed—and compare the dog with other dogs at the show. Most show dogs are competing for points toward their championship. At a large dog show, such as the Westminster Kennel Club show held over two days in New York City each February, a field of thousands of dogs is progressively thinned to a single Best in Show winner.

A variety of performance events are held that seek to provide dogs with an opportunity to perform the function for which they were originally bred. For instance, a saluki, a hound dog, may enter a lure coursing event to demonstrate its skill at pursuing swift prey. Small terriers may vocalize and lunge into a tunnel after “quarry” at an earth dog trial. Bloodhounds may follow a scent laid down by handlers at a tracking test. The puli, a herding dog, may gather a flock of sheep at a herding trial. Many performance events offer increasing levels of difficulty that are reflected in a range of titles. Once earned, these titles are entered into a dog’s permanent AKC record. Whether people choose to enter their dogs in formal competition, work with them, or simply enjoy their companionship, all dogs thrive on the bond that is fostered by a caring owner.

Contributed By:
Elizabeth M. Bodner

Tuesday 29 April 2014

CIVIL WRIGHTS AND CIVIL LIBERTIES

Civil Rights and Civil Liberties

INTRODUCTION

Civil Rights and Civil Liberties, political and social concepts referring to guarantees of freedom, justice, and equality that a state may make to its citizens. Although the terms have no precise meaning in law and are sometimes used interchangeably, distinctions may be made. Civil rights is used to imply that the state has a positive role in ensuring all citizens equal protection under law and equal opportunity to exercise the privileges of citizenship and otherwise to participate fully in national life, regardless of race, religion, sex, or other characteristics unrelated to the worth of the individual. Civil liberties is used to refer to guarantees of freedom of speech, press, or religion; to due process of law; and to other limitations on the power of the state to restrain or dictate the actions of individuals. The two concepts of equality and liberty are overlapping and interacting; equality implies the ordering of liberty within society so that the freedom of one person does not infringe on the rights of others, just as liberty implies the right to act in ways permitted to others.

HISTORY

The concept that human beings have inalienable rights and liberties that cannot justly be violated by others or by the state is linked to the history of democracy. It was first expressed by the philosophers of ancient Greece. Socrates, for example, chose to die rather than renounce the right to speak his mind in the search for wisdom. Somewhat later the Stoic philosophers formulated explicitly the doctrine of the rights of the individual (see Stoicism). Traces of libertarian doctrine appear in the Bible and in the writings of the Roman statesman Marcus Cicero and the Greek essayist Plutarch. Such ideas, however, did not gain a permanent place in the political structure of the Roman Empire and all but disappeared during medieval times.

Early Development

Individual freedom can survive only under a system of law by which both the sovereign and the governed are bound. Such a system of fundamental laws, whether written or embodied in tradition, is known as a constitution. The idea of government limited by law received effective expression for the first time in the Magna Carta (1215), which checked the power of the English king. The Magna Carta did not stem from democratic or egalitarian beliefs; rather, it was a treaty between king and nobility that defined their relationship and laid the basis for the concept that the ruler was subject to the law rather than above it. The development of constitutional government was slowed by the persistence of the ideas of absolutism, the belief that all political power should be in the hands of one individual, and divine right, which held that kings derived their power from—and were accountable only to—God. These beliefs were widely held throughout Europe until the 18th century. The notion that the people have the right to be asked to consent to acts of government did not arrive without a protracted struggle. The reigns of the Tudor and Stuart monarchs in England were marked by fierce conflicts between the Crown and Parliament.

On the European continent the struggle between authoritarian and libertarian principles developed around religious rather than secular issues. During the Reformation, freedom of religious belief and practice was a primary concern. Tolerance was rare; as late as 1612, for instance, members of the Unitarian sect were burned as heretics in England (see Unitarianism). Not until the end of the 18th century did the ideals of religious toleration become firmly established in Western civilization.

As a result of the English, American, and French revolutions, libertarian ideals were embodied in the structure of national governments. In England, the struggle between Parliament and the absolutist Stuart monarchs culminated in the so-called Glorious Revolution of 1688. King James II was expelled, and the new king, William III, gave royal assent (1689) to the Declaration of Rights (English Bill of Rights), which guaranteed constitutional government. Subsequently, the monarch’s prerogatives were limited by statute and custom. The idea of a constitutional system is described in the writings of the English philosopher John Locke, which profoundly influenced the leaders of the American colonies.

The 17th century was marked also by the growth of individual freedom in Great Britain. In the common law courts, for example, the judges became more concerned for the rights of those accused of crime, and procedural safeguards were established.

Spread of Civil Liberties

British colonists brought the concepts of limited government and individual freedom to the New World. The early laws of Virginia, Massachusetts, and other colonies reflected interest in the reform of criminal procedure that was emerging in Great Britain. A notable event in the history of civil liberties was the successful defense (1735) in New York by the Philadelphia lawyer Andrew Hamilton of the printer John Peter Zenger, who had been charged with seditious libel for criticisms of the colonial government in his publication the New York Weekly Journal. Hamilton established the principle that the government may not punish truthful publications of matters of public concern. See The Trial of John Peter Zenger.

The events leading to the American and French revolutions inspired writings that laid the foundations for modern ideas of civil liberties by such authors as the French philosophers Voltaire and Jean Jacques Rousseau, the British reformer John Wilkes and the philosopher Jeremy Bentham, the Anglo-American writer Thomas Paine, and the American statesmen Thomas Jefferson and James Madison. The Declaration of the Rights of Man and of the Citizen in France and the Bill of Rights of the Constitution of the United States formally established libertarian principles as a foundation of modern democracy.

Although civil liberties are often considered an integral part of democratic government, the principles of limited government and personal freedom were developed in England at a time when political power was held by an aristocratic upper class. Similarly, in the American colonies, many founding fathers did not favor democracy in the modern sense. Indeed, the framers of the U.S. Constitution provided a method of electing the nation’s president that avoids a direct popular vote. Conversely, history offers numerous examples of countries in which political power is formally vested in representative assemblies, but enforcement of law is arbitrary or despotic, and minorities have few safeguards against the tyranny of majorities.

III

CIVIL RIGHTS AND CIVIL LIBERTIES IN THE UNITED STATES

The civil rights and liberties of U.S. citizens are largely embodied in the Bill of Rights (the first ten amendments to the Constitution) and in similar provisions in state constitutions. The First Amendment guarantees freedom of speech, press, assembly, and religious exercise as well as separation of church and state (see Speech, Freedom of; Press, Freedom of the; Religious Liberty). The Fourth Amendment protects the privacy and security of the home and personal effects and prohibits unreasonable searches and seizures. The Fifth through Eighth amendments protect persons accused of crime; they guarantee, for example, the right to trial by jury, the right to confront hostile witnesses and to have legal counsel, and the privilege of not testifying against oneself. The Fifth Amendment also contains the general guarantee that no one shall be deprived of life, liberty, or property without due process of law (see Due Process of Law). Originally these amendments were binding only on the federal government. However, decisions by the Supreme Court of the United States have established that the Due Process Clause of the 14th Amendment (ratified in 1868) applies many of the guarantees in the Bill of Rights to actions by state and local governments.

Religious Freedom

Although religious freedom has not generally been curtailed in the United States, Roman Catholics, Jews, and members of such unconventional Protestant groups as the Oneida Community and the Church of Jesus Christ of Latter-day Saints have historically been discriminated against and sometimes have even been persecuted, although today overt discrimination has almost vanished.

The federal Civil Rights Act of 1964, as well as many state and local laws, prohibits religious discrimination. The government recognizes the right of religious pacifists to refuse to bear arms, even in time of war. The Supreme Court has ruled that this right, known as conscientious objection, need not be based only on religious training or belief in a supreme being. The Court has also upheld the right of Jehovah’s Witnesses to refuse to salute the flag because of religious objections.

Applying the principle of separation of church and state (see Church and State), the Court has struck down many attempts to use public funds to finance religious schools; at times, however, the Court has permitted the use of public funds for buildings and other nonsectarian programs of religious schools. In the 1960s the Court ruled that state-composed prayers and Bible reading in public schools violated the Constitution, a policy to which the Court has adhered. In 2000, for example, it struck down school-sponsored prayers at public high school football games. Efforts to reverse these rulings were unsuccessful, but in recent years the Court has been more permissive in allowing government aid to religion. For example, in certain cases it has upheld a community’s right to place religious displays on public property, and in 2002 it upheld a school voucher program in which public funds were largely to pay for education at religious private schools. At the same time, however, the Court has refused to require the government to carve out religious exemptions from generally applicable laws.

Freedom of Speech, Press, and Assembly

Civil liberties have been most endangered during periods of national emergency. In 1798 hostility toward revolutionary France led Congress to enact the Alien and Sedition Acts, which stripped aliens of nearly all civil rights and threatened freedom of speech and the press by prohibiting “false, scandalous and malicious writing” against the government, Congress, or the president. The constitutionality of these acts was never tested, but they soon expired, were not reenacted, and are now generally agreed to have been unconstitutional.

During the American Civil War (1861-1865), President Abraham Lincoln gave his principal military officers wide and unreviewed authority to arrest civilians for disloyal speech or acts. After World War I (1914-1918), fear of the newly established Communist government in the Soviet Union led to the harassment of suspected subversives by the U.S. Department of Justice.

The rise of National Socialism in Germany, the spread of communism, and the Great Depression of the 1930s all combined to arouse concern for the internal security of the United States. The federal legislative and executive power to deal with disloyal acts was enlarged. In 1940 Congress passed the Smith Act, which outlawed the advocacy of force and violence as a means of bringing about changes in government. In 1950 Congress adopted the Internal Security Act, which established a new federal agency for identifying and suppressing so-called subversive persons and organizations. Congress virtually outlawed the Communist Party in 1954, although membership in the party was not expressly made criminal. These statutes were upheld by the Supreme Court, but eventually were limited in scope and fell into disuse during the 1960s. In 1969 the Court adopted a constitutional standard that protects political speech unless “directed to inciting … imminent lawless action” and was likely to produce such action.

In the 1950s congressional and state investigating committees conducted widely publicized hearings at which thousands of individuals were questioned concerning their political activities and associations, if any, with the Communist Party. Among the legislators prominently identified with these investigations were Senators Patrick McCarran of Nevada and Joseph McCarthy of Wisconsin. The Supreme Court subsequently limited such proceedings.

New problems emerged during the 1960s and 1970s. Demonstrations by opponents of racial discrimination and the Vietnam War (1959-1975), and government attempts to restrict these demonstrations, led the Supreme Court to specify where, when, and how cities and states may limit the use of streets, parks, and other public places for purposes of protest. At the same time, certain symbolic forms of expression were employed by the protesters, leading to court rulings upholding criminal punishment for the burning of draft cards but reversing convictions for the mutilation of the American flag as a form of expression. The Court held in 1989 and 1990 that neither the federal government nor the states could single out the burning of the American flag for criminal penalties.

The attempted publication in 1971 by the New York Times and the Washington Post of the so-called Pentagon Papers led to a major Supreme Court decision that prior restraints on publication of national security material could not be enjoined unless such material “will surely result in direct, immediate and irreparable damage to our nation or its people.” See Censorship.

In 1964 the Supreme Court ruled for the first time that, to give the press breathing room, even false statements about public officials are protected by the First Amendment unless uttered with “actual malice”; that is, with knowledge of their falsehood or with reckless disregard of the facts. Later cases refined this decision but left to the discretion of the states whether to allow defamation actions brought by persons who are neither public officials nor public figures.

The Supreme Court also elaborated its 1957 ruling that obscenity is not constitutionally protected speech. Determining the content of obscenity has been difficult; in 1973 it was defined as speech that, taken as a whole, appeals to the prurient interest, is patently offensive in depicting sexual conduct, and lacks serious literary, political, or scientific value. This vague definition has led to numerous lawsuits involving explicit sexual material. Conservative religious groups and some feminists have attempted to restrict the distribution of sexually explicit material that is not obscene. The movement achieved limited success, but civil libertarians have led efforts to combat this form of censorship. In 1997 the Court struck down a federal law that banned nonobscene but sexually explicit material on the Internet. The Court reasoned that Congress may not prohibit circulation to adults of constitutionally protected speech simply because children might see it.

One of the most controversial First Amendment cases of the late 1970s did not reach the Supreme Court. When a U.S. Nazi group sought to march in Skokie, Illinois, the home of many Jewish survivors of German concentration camps, emotions were aroused, and the city enacted laws designed to prevent the march. Both federal and state courts upheld the right of this Nazi group, which was represented by the American Civil Liberties Union, to express itself peaceably.

The Court has broadened constitutional protection for many other forms of speech, including commercial speech. In the 1990s, it struck down several attempts to ban advertising, including liquor advertising, said to be harmful.

Criminal Trials and Due Process of Law

Thousands of Supreme Court rulings have been concerned with the rights of persons accused of crimes. Defendants in state as well as federal criminal cases are assured that they cannot be imprisoned for an offense unless represented by a lawyer, or counsel; if a defendant is impoverished, such counsel must be supplied by the government. Defendants must be warned that they may not be questioned until counsel is provided, and defendants may not be convicted on the basis of confessions obtained by coercion. The Court also ruled that prosecutors may not exclude people from juries on grounds of race or sex.

The Fifth Amendment privilege against self-incrimination was the most controversial constitutional protection during the 1950s and 1960s, when it was invoked by, among others, individuals accused of subversive activities and participation in organized crime. The Court’s interpretation of the Fourth Amendment has also generated controversy; its provisions protecting the security of the person and of dwellings have been cited in disallowing convictions based on evidence obtained by the police illegally. The Court in the 1970s began to narrow its interpretation, a process that has continued into the 21st century as the public has come to favor crime-control measures over the rights of defendants. This climate of opinion has also led to more frequent use of capital punishment, although the Court has limited the crimes for which death may be the punishment. The Court has also prescribed procedures that must be followed before the death penalty may be given. At the same time, it has limited the right of prisoners to appeal their convictions on constitutional grounds.

Criminal Trials and Due Process during the ‘War on Terror’

Following the September 11, 2001, terrorist attacks on the World Trade Center and the Pentagon by international terrorists, President George W. Bush invoked his constitutional authority as commander-in-chief and signed a military order allowing the government to detain and conduct military trials of noncitizens suspected of terrorism. The U.S. military proceeded to detain as “unlawful enemy combatants” hundreds of foreign nationals who were captured during hostilities in Afghanistan and elsewhere. The government held them indefinitely at the U.S. naval base at Guantánamo Bay, Cuba, without bringing criminal charges or allowing them legal counsel. The military also detained two American citizens as unlawful enemy combatants.

In 2004 the Supreme Court considered the constitutionality of indefinite detentions of enemy combatants. In the case Hamdi v. Rumsfeld, the Court upheld the authority of the president of the United States to classify U.S. citizens as unlawful enemy combatants and to detain them without charges. However, the Court ruled that such detainees are entitled to challenge the government’s case against them before an impartial judge. In addition, detainees have the right to an attorney. In Rasul v. Bush, the Court ruled that foreign detainees held at Guantánamo Bay have the right to challenge their detention in U.S. courts.

In June 2006 the Supreme Court addressed the issue of military trials for accused enemy combatants. In Hamdan v. Rumsfeld the Court ruled that proposed military tribunals for alleged unlawful combatants violated federal statute and the Uniform Code of Military Justice (UCMJ), in part because the UCMJ incorporates Common Article 3 of the Geneva Conventions—most importantly its requirement of trials before “regularly constituted courts.” The Court found that the Bush administration’s proposed military tribunals were illegal because, unlike normal court-martial proceedings, trials in these commissions allowed for evidence obtained by coercion and hearsay, and because the accused were not allowed to be present at all times during the trial or to see all the evidence against them.

In September 2006 the U.S. Congress responded to the Supreme Court’s ruling by passing the Military Commissions Act of 2006. The new law reflected Congress’s insistence that torture be prohibited but also permitted under certain conditions the admission of evidence obtained by coercion. The new law also denied the right of habeas corpus to noncitizens designated as unlawful enemy combatants by the president or secretary of defense. The law affirmed the president's power to hold people as enemy combatants based on a wide range of conduct, some of it falling well short of actual military hostilities.

Privacy

A constitutional right of privacy, drawn from the Bill of Rights provisions protecting the security of home and person, as well as freedom of association, was first recognized by the Supreme Court in 1965. In Griswold v. Connecticut the Court struck down a state law that prohibited the use of contraceptives by a married couple. The decision was later extended to protect the rights of single persons and, in the Roe v. Wade decision of 1973, the right of women to abort an unwanted pregnancy. In 1980, however, the Court refused to apply this ruling to require the federal government to bear the cost of abortions for women who could not afford them. Efforts to reverse Roe v. Wade judicially or by constitutional amendment were unsuccessful. A divided Supreme Court in 1992 reaffirmed the core holding of Roe while further limiting its scope.

Other test cases of rights of privacy during this period concerned wiretapping and eavesdropping on private conversations, widespread dissemination of personal information through computers, access to information in government files, and the use without consent of pictures and names of celebrities. Although the courts have given some protection to privacy, the limitations have been relatively minor. For example, the Supreme Court ruled in 2000 that Congress could prohibit states from selling personal information on state drivers’ licenses and motor-vehicle registration records. Additional protection has resulted from legislative enactments such as the federal Privacy Act of 1974 and various state statutes.

The Patriot Act, antiterrorism legislation passed in the aftermath of the September 11 attacks, significantly expanded the federal government’s surveillance powers. Federal agents were given greater authority to wiretap telephones, to monitor e-mail and Internet use, and to secretly search a suspect’s home or office. These powers were further widened by the Intelligence Reform and Terrorism Prevention Act of 2004, which authorized the sharing of personal information from public and private databases. Civil liberties advocates warned that this provision had the potential to lead to unchecked data surveillance, but supporters of the law said adequate safeguards were in place to protect privacy. See also Surveillance, Electronic.

Civil liberties advocates were again concerned when it was revealed in December 2005 that President George W. Bush had signed a presidential order in 2002 authorizing the National Security Agency to eavesdrop without judicial warrants on the overseas electronic communications of U.S. citizens and foreign nationals in the United States. Many legal experts believed the order violated the 1978 Foreign Intelligence Surveillance Act (FISA), which set up a special court to hear government requests for domestic wiretaps of U.S. citizens or foreign nationals in investigations involving espionage. Although the Patriot Act further amended FISA by lowering the standard for court-approved eavesdropping to include possible terrorists linked to foreign intelligence services, it still required approval by the FISA special court for wiretapping. FISA was enacted in response to abuses by the Federal Bureau of Investigation and the Central Intelligence Agency, which were found to have wiretapped individuals and organizations engaged in civil rights and anti-Vietnam War protests and other First Amendment-protected activities during the 1960s and 1970s. To prevent abuses, FISA prohibited any electronic surveillance not authorized by the special court.

In hearings before the U.S. Congress, Attorney General Alberto Gonzales aggressively countered the claim that the NSA wiretapping was illegal, citing Bush’s authority as commander in chief. Gonzales said the program’s legality was also established by a congressional resolution, the 2001 Authorization for Use of Military Force, which authorized the president to use “all necessary and appropriate force” to prevent future acts of terrorism. Many members of Congress, however, said the resolution had nothing to do with warrantless electronic surveillance. The conflict raised serious questions not only about privacy but also about the limits of presidential power and the system of checks and balances during wartime. See also Signing Statement.

Minority Rights

Civil Rights for Blacks

The most critical civil rights issue in the United States has concerned the status of its black minority. After the Civil War the former slaves’ status as free people entitled to the rights of citizenship was established by the 13th and 14th Amendments, ratified in 1865 and 1868, respectively. The 15th Amendment, ratified in 1870, prohibited race, color, or previous condition of servitude as grounds for denying or abridging the rights of citizens to vote. In addition to these constitutional provisions, Congress enacted several statutes defining civil rights more particularly. The Supreme Court, however, held several of these unconstitutional, including an 1875 act prohibiting racial discrimination by innkeepers, public transportation providers, and places of amusement.

During the period of Reconstruction the Republican-dominated federal government maintained troops in the southern states. Blacks voted and held political offices, including seats in Congress. Two blacks became senators, and 20 were elected to the House of Representatives during this era. The Reconstruction era aroused the bitter opposition of most southern whites. The period came to an end in 1877, when a political compromise between the Republican Party and southern leaders of the Democratic Party led to the withdrawal of federal troops from the South.

In the last two decades of the 19th century, blacks in the South were disfranchised and stripped of other rights through discriminatory legislation and unlawful violence. Separate facilities for whites and blacks became a basic rule in southern society. In Plessy v. Ferguson, an 1896 case involving the segregation of railroad passengers, the Supreme Court held that “separate but equal” public facilities did not violate the Constitution and refused to acknowledge that the separate facilities in use were not in fact equal.

During the first half of the 20th century, racial exclusion, either overt or covert, was practiced in most areas of American life. During World War II (1939-1945) black leaders such as A. Philip Randolph protested segregation in military service, and some reforms were introduced. In 1948 President Harry S. Truman signed an executive order integrating the armed forces. The 1954 Supreme Court decision in Brown v. Board of Education represented a turning point; reversing the 1896 “separate but equal” ruling, the Court held that compulsory segregation in public schools denied black children equal protection under the law. It later directed, ineffectually, that desegregated educational facilities be furnished “with all deliberate speed.” Subsequent decisions outlawed racial exclusion or discrimination in all government facilities. The Court also upheld federal laws barring discrimination in interstate commerce, such as public transportation. A state law against racial intermarriage was also ruled invalid (see Miscegenation).

School desegregation was resisted in the South. Federal determination to enforce the court decision was demonstrated in Little Rock, Arkansas, in 1957, when President Dwight Eisenhower dispatched troops to secure admission of black students into a “white” high school. Nevertheless, in the Deep South progress toward integration was negligible in the years following the Supreme Court decision. In 1966, for example, the overwhelming majority of southern schools remained segregated. By 1974, however, some 44 percent of black students in the South attended integrated schools, and by the early 1980s the number was approximately 80 percent.

In the North and West many black students also attended segregated schools. Such segregation was considered unconstitutional only where it could be proven to have originated in unlawful state action. Public controversy, sometimes violent, continued over the issue of transporting children in school buses long distances from their homes in order to achieve integration. Busing had become necessary because of the concentration of minority populations in the central areas of many cities. The Supreme Court dealt a blow to such busing in July 1974 by, in effect, barring it across school-district lines except on a voluntary basis.

Civil rights for blacks became a major national political issue in the 1950s. The first federal civil rights law since the Reconstruction period was enacted in 1957. It called for the establishment of a U.S. Commission on Civil Rights and authorized the U.S. attorney general to enforce voting rights. In 1960 this legislation was strengthened, and in 1964 a more sweeping civil rights bill outlawed racial discrimination in public accommodations and by employers, unions, and voting registrars. Deciding that normal judicial procedures were too slow in assuring minority registration and voting, Congress passed a voting rights bill in 1965. The law suspended (and amendments later banned) use of literacy or other voter-qualification tests that had sometimes served to keep blacks off voting lists, authorized appointment of federal voting examiners in areas not meeting certain voter-participation requirements, and provided for federal court suits to bar discriminatory poll taxes, which were ended by a Supreme Court decision and the 24th Amendment (ratified in 1964). In the aftermath of the assassination of the civil rights leader Martin Luther King, Jr., Congress in 1968 prohibited racial discrimination in federally financed housing, but later efforts to strengthen the law failed. See also Segregation in the United States.

Affirmative Action

An important constitutional issue that has caused public controversy is whether, and to what degree, public and private institutions may use affirmative action to help members of minority groups obtain better employment or schooling. In the Regents of the University of California v. Bakke case in 1978, the Supreme Court held that it was unconstitutional for the University of California Medical School at Davis to set an absolute quota for the admission of minority candidates, but said that race can be taken into account for the setting of numerical goals that were not disguised quotas. The Court later ruled that racial preferences by a private corporation designed to remedy prior discrimination did not violate the Civil Rights Act.

A changing political climate in the 1980s and 1990s, however, led to the repeal of many affirmative action programs. In 1995 the Court said that all public affirmative action plans must be strictly scrutinized. The Court hinted strongly that only those plans designed to remedy past acts of discrimination would survive. Furthermore, many lower courts began to openly reject the finding in the Bakke case that colleges and universities were permitted to seek racial diversity among their student bodies by giving special consideration to minority applicants.

Nevertheless, in the first major decision on affirmative action since the Bakke case in 1978, the Supreme Court in 2003 reaffirmed racial diversity as a goal of college and university admissions programs. The case involved the University of Michigan Law School’s admission program, which considered race, among other qualities, in evaluating each applicant. In a 5 to 4 decision the Supreme Court upheld the law school’s affirmative action program, finding that there was a “compelling public interest” in achieving diversity as long as quotas were not used. The decision in Grutter v. Bollinger came despite briefs filed against affirmative action by the administration of President George W. Bush. The decision did not rescind state laws that forbid affirmative action programs, such as those passed by popular initiative in California and Washington. Civil rights organizations hailed the ruling as a historic victory. Opponents of the decision took note of the Court’s opinion that affirmative action should only be necessary for another 25 years.

Civil Rights for Hispanics and Asian Americans

Civil rights have also been denied to Hispanic Americans, particularly Puerto Ricans in the East and Mexican Americans in the Southwest. The problem has followed traditional paths, as rights have been denied in employment, housing, and access to the judicial system.

Asian Americans also have suffered deprivations of civil rights since at least the late 19th century. The forced removal and incarceration of persons of Japanese descent from the West Coast during World War II, which was upheld by the Supreme Court, was a major violation of civil liberties for which Congress apologized and provided reparations in 1990 (see Japanese American Internment). Asians faced low immigration quotas before the laws were amended in 1965, 1968, and 1977, and in parts of the United States, Asian Americans have been denied equal rights in housing and employment.

Rights of Women

Historically, American women have been denied their civil rights in suffrage (they were unable to vote until a 1920 constitutional amendment), employment, and other areas. In the 1960s women organized to demand legal equality with men and, after passage of the Civil Rights Act of 1964, made many gains, especially in employment. During the 1970s efforts continued to change not only unfair practices but also outmoded attitudes toward the role of women in society. In 1972 Congress passed the Equal Rights Amendment (ERA) to the Constitution and submitted it to the states for ratification. The ERA, however, which was designed to eliminate legal discrimination against women, failed to win the approval of a sufficient number of states; by the June 1982 deadline only 35 of the required 38 states had ratified the amendment. Although the ERA failed, beginning in the 1970s the Supreme Court ruled that laws treating men and women differently were constitutionally suspect. In the landmark case United States v. Virginia in 1996, the Court said that sex discrimination is unconstitutional unless the state can advance an “exceedingly persuasive justification.”

Women have continued to make gains in certain trades and professions, including financial services, medicine, and law, but problems remain in many areas. The Civil Rights Act of 1991 extended to women victims of job bias the right to sue their employers for monetary damages. The act also established a commission to probe the “glass ceiling” that has prevented women and other minorities from advancing to top management. See Women’s Rights.

Rights of Other Minorities

The struggle for civil rights has not been confined to blacks, Hispanic Americans, Asian Americans, and women. Native Americans for decades were forcibly deprived of their lands and denied civil rights. In 1968 Congress enacted the Indian Civil Rights Act, and the federal courts have heard a number of suits designed to restore to Native American tribes rights to their ancestral lands.

The elderly have also been deprived of their civil rights, especially in employment and to some degree in housing. Federal and state laws have been only partially successful in solving this problem. Former prisoners and mental patients have suffered legal disabilities after their confinement ended, and resident aliens are sometimes denied equal employment opportunities.

Homosexuals, historically, have not had full civil rights because of social and sexual taboos. The number of judicial decisions and laws enacted at the local level to protect gay men and women from discrimination has increased, but the degree of prejudice was heightened in the 1980s by the concern about Acquired Immune Deficiency Syndrome (AIDS). In 1986 the Supreme Court ruled that the Constitution does not bar criminal prosecution for private homosexual relations between consenting adults. Several local governments acted to curtail the rights of lesbians and gay men. By the early 1990s the gay community had organized more effectively than ever before in the effort to assert their rights. In 1996 the Supreme Court ruled that state and local governments cannot make it more difficult for homosexuals than other groups to seek protection through antidiscrimination legislation. And in 2003, in a landmark decision, the Supreme Court overturned its 1986 ruling and nullified laws in 13 states that criminalized gay sexual practices. The Court asserted that gays are “entitled to respect for their private lives” and that “the state cannot demean their existence or control their destiny by making their private sexual conduct a crime.” See also Gay Rights Movement.

CIVIL RIGHTS AND CIVIL LIBERTIES IN CANADA

Although bordering the United States and sharing a similar legal system, the development of civil rights and civil liberties in Canada has followed a different path, in large part because Canada had no equivalent to the U.S. Bill of Rights until very recently. Provincial codes provided for several rights of the kind protected by the U.S. Bill of Rights, but they did not apply throughout Canada and were far from complete. After World War II, a political movement in Canada championed a Canadian Bill of Rights, and in the 1950s the Supreme Court of Canada issued some rulings that suggested it might develop civil rights concepts on its own. In 1960 the Canadian Parliament enacted a Bill of Rights, but it applied only to the federal government, not to the provinces. Moreover, the Bill of Rights was an ordinary statute that lacked the force of an amendment to the Constitution of Canada.

Beginning in the late 1960s, Prime Minister Pierre Trudeau initiated a complex political and legal battle that ultimately led, in 1982, to the adoption of the Canadian Charter of Rights and Freedoms as part of the Canadian constitution. The charter established a menu of civil rights and liberties similar to those set out in the U.S. Constitution. Additionally, the charter expressly provides for the right of judicial review, permitting those who claim that their rights under the charter have been infringed or denied to seek remedies in court. One major difference between the charter and the U.S. Constitution is that some of the charter’s provisions may be overridden in certain circumstances by both the Canadian federal government and provincial legislatures. In the United States, neither Congress nor the state legislatures may pass a law that conflicts with rights protected by the Constitution.

The charter spells out a host of “fundamental freedoms,” including freedom of conscience and religion; freedom of thought, belief, opinion, and expression, including freedom of the press; freedom of peaceful assembly; and freedom of association. It provides “mobility rights” that give Canadians the right to enter and leave Canada and to settle and live in any province. The charter also spells out a host of procedural rights in criminal prosecutions, including the rights of the accused against self-incrimination, double jeopardy, cruel and unusual punishments, and unreasonable search and seizure, and the rights to be presumed innocent, to speedy trial, to representation by counsel, and to habeas corpus. The charter’s version of the due process clauses in the U.S. Constitution declares that “everyone has the right to life, liberty and security of the person” and cannot be deprived of these rights “except in accordance with the principles of fundamental justice.”

The charter also provides that all individuals are equal under the law and may not be discriminated against by the law on the basis of race, national or ethnic origin, color, religion, sex, age, or mental or physical disability. This list of protections is more extensive than provided for in the Equal Protection Clause of the U.S. Constitution or than accepted by the U.S. Supreme Court. The charter also expressly permits laws, programs, and activities whose goal is “the amelioration of conditions of disadvantaged individuals.”

Signifying Canada’s bilingual heritage, the charter has extensive provisions dealing with the rights of French and English speakers. These include the rights of children to obtain instruction in their birth language, whether English or French, and the right to speak either language in Parliament and the courts.

Although the Canadian Charter of Rights and Freedoms has had legal effect only since 1982, it seems to have prompted Canadians to take their cases to courts in larger numbers, and it has prompted a greater constitutional activism than before from Canada’s highest court. The Canadian Supreme Court has followed the lead of the U.S. Supreme Court in several instances, striking down, for example, antiabortion legislation and laws restricting commercial advertising, and excluding evidence from trial if the defendant was not advised of the right to a lawyer.

INTERNATIONAL CONCERNS

To establish the principles of civil liberties and civil rights on an international basis, the United Nations Charter was drawn up after World War II (1939-1945); it states that one of the purposes of the UN is to promote and encourage respect for “human rights and for fundamental freedoms for all without distinction as to race, sex, language or religion.” In 1946 a UN Commission on Human Rights was established. In 1948 the General Assembly adopted a Universal Declaration of Human Rights prepared by the commission and embodying the 18th-century ideals of liberty, equality, and fraternity. This declaration, however, is not binding on member states.

Almost all nations deny civil rights to disfavored minorities within their borders. A major obstacle to international protection of human rights is the opposition of most countries to interference with their internal affairs, including questions of the rights of their own citizens. To some degree this difficulty has been overcome through regional arrangements and implementing bodies such as the European Commission on Human Rights and the Inter-American Commission on Human Rights.

The administration of President Jimmy Carter in the late 1970s introduced human rights as an element of foreign policy. This initiative was unevenly pressed and sometimes ineffectual, but it increased international awareness of the gravity of the problem of securing human rights for all people. The administration of President Ronald Reagan took a less aggressive stance on human rights violations, claiming that quiet diplomacy was more effective than public threats. During the administrations of Presidents George H. W. Bush and Bill Clinton, human rights issues became increasingly intertwined with international trade and commercial treaties. Controversy surrounded the granting of most-favored-nation status to countries alleged to have violated human rights, such as China. Most-favored-nation status guarantees that a country will receive the same terms offered to other trade partners in commercial treaties.

International revulsion at atrocities committed in several countries during the 1990s, including Rwanda and the former Yugoslavia, led to the establishment of international tribunals to try the most brutal war crimes. A permanent body, the International Criminal Court, began operation in 2002 to try individuals accused of war crimes, genocide, crimes against humanity, and crimes of aggression. Proponents said the existence of the court would help deter future human rights abuses. The United States does not participate in the International Criminal Court and does not recognize its authority.

Contributed By:
Norman Dorsen
Jethro K. Lieberman

Monday 28 April 2014

INTRODUCTION ON ASTRONOMY

Astronomy

INTRODUCTION

Astronomy, study of the universe and the celestial bodies, gas, and dust within it. Astronomy includes observations and theories about the solar system, the stars, the galaxies, and the general structure of space. Astronomy also includes cosmology, the study of the universe and its past and future. People who study astronomy are called astronomers, and they use a wide variety of methods to perform their research. These methods usually involve ideas of physics, so most astronomers are also astrophysicists, and the terms astronomer and astrophysicist are basically identical. Some areas of astronomy also use techniques of chemistry, geology, and biology.

Astronomy is the oldest science, dating back thousands of years to when primitive people noticed objects in the sky overhead and watched the way the objects moved. In ancient Egypt, the first appearance of certain stars each year marked the onset of the seasonal flood, an important event for agriculture. In 17th-century England, astronomy provided methods of keeping track of time that were especially useful for accurate navigation. Astronomy has a long tradition of practical results, such as our current understanding of the stars, day and night, the seasons, and the phases of the Moon. Much of today's research in astronomy does not address immediate practical problems. Instead, it involves basic research to satisfy our curiosity about the universe and the objects in it. One day such knowledge may well be of practical use to humans. See also History of Astronomy.

AMATEUR ASTRONOMY

Astronomers use tools such as telescopes, cameras, spectrographs, and computers to analyze the light that astronomical objects emit. Amateur astronomers observe the sky as a hobby, while professional astronomers are paid for their research and usually work for large institutions such as colleges, universities, observatories, and government research institutes. Amateur astronomers make valuable observations, but are often limited by lack of access to the powerful and expensive equipment of professional astronomers.

A wide range of astronomical objects is accessible to amateur astronomers. Many solar system objects—such as planets, moons, and comets—are bright enough to be visible through binoculars and small telescopes. Small telescopes are also sufficient to reveal some of the beautiful detail in nebulas—clouds of gas and dust in our Milky Way Galaxy. Many amateur astronomers observe and photograph these objects. The increasing availability of sophisticated electronic instruments and computers over the past few decades has made powerful equipment more affordable and allowed amateur astronomers to expand their observations to much fainter objects. Amateur astronomers sometimes share their observations by posting their photographs on the World Wide Web, a network of information based on connections between computers.

Amateurs often undertake projects that require numerous observations over days, weeks, months, or even years. By searching the sky over a long period of time, amateur astronomers may observe things in the sky that represent sudden change, such as new comets or novas (stars that brighten suddenly). This type of consistent observation is also useful for studying objects that change slowly over time, such as variable stars and double stars. Amateur astronomers observe meteor showers, sunspots, and groupings of planets and the Moon in the sky. They also participate in expeditions to places in which special astronomical events—such as solar eclipses and meteor showers—are most visible. Several organizations, such as the Astronomical League and the American Association of Variable Star Observers, provide meetings and publications through which amateur astronomers can communicate and share their observations.

III

HOW ASTRONOMERS WORK

Professional astronomers usually have access to powerful telescopes, detectors, and computers. Most work in astronomy includes three parts, or phases. Astronomers first observe astronomical objects by guiding telescopes and instruments to collect the appropriate information. Astronomers then analyze the images and data. After the analysis, they compare their results with existing theories to determine whether their observations match with what theories predict, or whether the theories can be improved. Some astronomers work solely on observation and analysis, and some work solely on developing new theories.

Astronomy is such a broad topic that astronomers specialize in one or more parts of the field. For example, the study of the solar system is a different area of specialization than the study of stars. Astronomers who study our galaxy, the Milky Way, often use techniques different from those used by astronomers who study distant galaxies. Many planetary astronomers, such as scientists who study Mars, may have geology backgrounds and not consider themselves astronomers at all. Solar astronomers use different telescopes than nighttime astronomers use, because the Sun is so bright. Theoretical astronomers may never use telescopes at all. Instead, these astronomers use existing data or sometimes only previous theoretical results to develop and test theories. An increasing field of astronomy is computational astronomy, in which astronomers use computers to simulate astronomical events. Examples of events for which simulations are useful include the formation of the earliest galaxies of the universe or the explosion of a star to make a supernova.

Astronomers learn about astronomical objects by observing the energy they emit. These objects emit energy in the form of electromagnetic radiation. This radiation travels throughout the universe in the form of waves and can range from gamma rays, which have extremely short wavelengths, to visible light, to radio waves, which are very long. The entire range of these different wavelengths makes up the electromagnetic spectrum.

Astronomers gather different wavelengths of electromagnetic radiation depending on the objects that are being studied. The techniques of astronomy are often very different for studying different wavelengths. Conventional telescopes work only for visible light and the parts of the spectrum near visible light, such as the shortest infrared wavelengths and the longest ultraviolet wavelengths. Earth’s atmosphere complicates studies by absorbing many wavelengths of the electromagnetic spectrum. Gamma-ray astronomy, X-ray astronomy, infrared astronomy, ultraviolet astronomy, radio astronomy, visible-light astronomy, cosmic-ray astronomy, gravitational-wave astronomy, and neutrino astronomy all use different instruments and techniques.

Observation

Observational astronomers use telescopes or other instruments to observe the heavens. The astronomers who do the most observing, however, probably spend more time using computers than they do using telescopes. A few nights of observing with a telescope often provide enough data to keep astronomers busy for months analyzing the data.

Optical Astronomy

Until the 20th century, all observational astronomers studied the visible light that astronomical objects emit. Such astronomers are called optical astronomers, because they observe the same part of the electromagnetic spectrum that the human eye sees. Optical astronomers use telescopes and imaging equipment to study light from objects. Professional astronomers today hardly ever actually look through telescopes. Instead, a telescope sends an object’s light to a photographic plate or to an electronic light-sensitive computer chip called a charge-coupled device, or CCD. CCDs are about 50 times more sensitive than film, so today's astronomers can record in a minute an image that would have taken about an hour to record on film.

Telescopes may use either lenses or mirrors to gather visible light, permitting direct observation or photographic recording of distant objects. Those that use lenses are called refracting telescopes, since they use the property of refraction, or bending, of light (see Optics: Reflection and Refraction). The largest refracting telescope is the 40-in (1-m) telescope at the Yerkes Observatory in Williams Bay, Wisconsin, founded in the late 19th century. Lenses bend different colors of light by different amounts, so different colors focus slightly differently. Images produced by large lenses can be tinged with color, often limiting the observations to those made through filters. Filters limit the image to one color of light, so the lens bends all of the light in the image the same amount and makes the image more accurate than an image that includes all colors of light. Also, because light must pass through lenses, lenses can only be supported at the very edges. Large, heavy lenses are so thick that all the large telescopes in current use are made with other techniques.

Reflecting telescopes, which use mirrors, are easier to make than refracting telescopes and reflect all colors of light equally. All the largest telescopes today are reflecting telescopes. The largest single telescopes are the Keck telescopes at Mauna Kea Observatory in Hawaii. The Keck telescope mirrors are 394 in (10.0 m) in diameter. Mauna Kea Observatory, at an altitude of 4,205 m (13,796 ft), is especially high. The air at the observatory is very clear, so many major telescope projects are located there.

The Hubble Space Telescope (HST), a reflecting telescope that orbits Earth, has returned the clearest images of any optical telescope. The main mirror of the HST is only 94 in (2.4 m) across, far smaller than that of the largest ground-based reflecting telescopes. Turbulence in the atmosphere makes observing objects as clearly as the HST can see impossible for ground-based telescopes. HST images of visible light are about five times finer than any produced by ground-based telescopes. Giant telescopes on Earth, however, collect much more light than the HST can. Examples of such giant telescopes include the twin 32-ft (10-m) Keck telescopes in Hawaii and the four 26-ft (8-m) telescopes in the Very Large Telescope array in the Atacama Desert in northern Chile (the nearest city is Antofagasta, Chile). Often astronomers use space- and ground-based telescopes in conjunction. See also Space Telescope.

Astronomers usually share telescopes. Many institutions with large telescopes accept applications from any astronomer who wishes to use the instruments, though others have limited sets of eligible applicants. The institution then divides the available time among successful applicants and assigns each astronomer an observing period. Astronomers can collect data from telescopes remotely. Data from Earth-based telescopes can be sent electronically over computer networks. Data from space-based telescopes reach Earth through radio waves collected by antennas on the ground.

Gamma-Ray and X-Ray Astronomy

Gamma rays have the shortest wavelengths. Special telescopes in orbit around Earth, such as the National Aeronautics and Space Administration’s (NASA’s) Compton Gamma-Ray Observatory, gather gamma rays before Earth’s atmosphere absorbs them. X rays, the next shortest wavelengths, also must be observed from space. NASA’s Chandra X-Ray Observatory (CXO) is a school-bus-sized spacecraft that began studying X rays from orbit in 1999. See also Gamma-Ray Astronomy; X-Ray Astronomy.

Ultraviolet Astronomy

Ultraviolet light has wavelengths longer than X rays, but shorter than visible light. Ultraviolet telescopes are similar to visible-light telescopes in the way they gather light, but the atmosphere blocks most ultraviolet radiation. Most ultraviolet observations, therefore, must also take place in space. Most of the instruments on the Hubble Space Telescope (HST) are sensitive to ultraviolet radiation (see Ultraviolet Astronomy). Humans cannot see ultraviolet radiation, but astronomers can create visual images from ultraviolet light by assigning particular colors or shades to different intensities of radiation.

Infrared Astronomy

Infrared astronomers study parts of the infrared spectrum, which consists of electromagnetic waves with wavelengths ranging from just longer than visible light to 1,000 times longer than visible light. Earth’s atmosphere absorbs infrared radiation, so astronomers must collect infrared radiation from places where the atmosphere is very thin, or from above the atmosphere. Observatories for these wavelengths are located on certain high mountaintops or in space (see Infrared Astronomy). Most infrared wavelengths can be observed only from space. Every warm object emits some infrared radiation. Infrared astronomy is useful because objects that are not hot enough to emit visible or ultraviolet radiation may still emit infrared radiation. Infrared radiation also passes through interstellar and intergalactic gas and dust more easily than radiation with shorter wavelengths. Further, the brightest part of the spectrum from the farthest galaxies in the universe is shifted into the infrared.

Radio Astronomy

Radio waves have the longest wavelengths. Radio astronomers use giant dish antennas to collect and focus signals in the radio part of the spectrum (see Radio Astronomy). These celestial radio signals, often from hot bodies in space or from objects with strong magnetic fields, come through Earth's atmosphere to the ground. Radio waves penetrate dust clouds, allowing astronomers to see into the center of our galaxy and into the cocoons of dust that surround forming stars.

Study of Other Emissions

Sometimes astronomers study emissions from space that are not electromagnetic radiation. Some of the particles of interest to astronomers are neutrinos, cosmic rays, and gravitational waves. Neutrinos are tiny particles with no electric charge and very little or no mass. All stars emit neutrinos, but neutrino detectors on Earth receive neutrinos only from the Sun and supernovas. Most neutrino telescopes consist of huge underground tanks of liquid. These tanks capture a few of the many neutrinos that strike them, while the vast majority of neutrinos pass right through the tanks.

Cosmic rays are electrically charged particles that come to Earth from outer space at almost the speed of light. They are made up of negatively charged particles called electrons and positively charged nuclei of atoms. Astronomers do not know where most cosmic rays come from, but they use cosmic-ray detectors to study the particles. Cosmic-ray detectors are usually grids of wires that produce an electrical signal when a cosmic ray passes close to them.

Gravitational waves are a predicted consequence of the general theory of relativity developed by German-born American physicist Albert Einstein. Since the 1960s astronomers have been building detectors for gravitational waves. Older gravitational-wave detectors were huge instruments that surrounded a carefully measured and positioned massive object suspended from the top of the instrument. Lasers trained on the object were designed to measure the object’s movement, which theoretically would occur when a gravitational wave hit the object. No gravitational waves have yet been detected. Gravitational waves should be very weak, and the instruments are probably not yet sensitive enough to register them. In the 1970s and 1980s American physicists Joseph Taylor and Russell Hulse observed indirect evidence of gravitational waves by studying systems of double pulsars. A new generation of gravitational-wave detectors, developed in the 1990s, uses interferometers to measure distortions of space that would be caused by passing gravitational waves.

Some objects emit radiation more strongly in one wavelength than in another, but a set of data across the entire spectrum of electromagnetic radiation is much more useful than observations in any one wavelength. For example, the supernova remnant known as the Crab Nebula has been observed in every part of the spectrum, and astronomers have used all the discoveries together to make a complete picture of how the Crab Nebula is evolving.

Analysis and Theory

Whether astronomers take data from a ground-based telescope or have data radioed to them from space, they must then analyze the data. Usually the data are handled with the aid of a computer, which can carry out various manipulations the astronomer requests. For example, some of the individual picture elements, or pixels, of a CCD may be slightly more sensitive than others. Consequently, astronomers sometimes take images of blank sky to measure which pixels appear brighter. They can then take these variations into account when interpreting the actual celestial images. Astronomers may write their own computer programs to analyze data or, as is increasingly the case, use certain standard computer programs developed at national observatories or elsewhere.

Often an astronomer uses observations to test a specific theory. Sometimes, a new experimental capability allows astronomers to study a new part of the electromagnetic spectrum or to see objects in greater detail or through special filters. If the observations do not verify the predictions of a theory, the theory must be discarded or, if possible, modified.

EARTH'S NIGHT SKY

Up to about 3,000 stars are visible at a time from Earth with the unaided eye, far away from city lights, on a clear night. A view at night may also show several planets and perhaps a comet or a meteor shower. Increasingly, human-made light pollution is making the sky less dark, limiting the number of visible astronomical objects. During the daytime the Sun shines brightly. The Moon and bright planets are sometimes visible early or late in the day but are rarely seen at midday.

Earth's Relative Motion

Earth moves in two basic ways: It turns in place, and it revolves around the Sun. Earth turns around its axis, an imaginary line that runs down its center through its North and South poles. The Moon also revolves around Earth. All of these motions produce day and night, the seasons, the phases of the Moon, and solar and lunar eclipses.

Night, Day, and Seasons

Earth is about 12,000 km (about 7,000 mi) in diameter. As it revolves, or moves in a circle, around the Sun, Earth spins on its axis. This spinning movement is called rotation. Earth’s axis is tilted 23.5° with respect to the plane of its orbit. Each time Earth rotates on its axis, it goes through one day, a cycle of light and dark. Humans artificially divide the day into 24 hours and then divide the hours into 60 minutes and the minutes into 60 seconds.

Earth revolves around the Sun once every year, or 365.25 days (most people use a 365-day calendar and take care of the extra 0.25 day by adding a day to the calendar every four years, creating a leap year). The orbit of Earth is almost, but not quite, a circle, so Earth is sometimes a little closer to the Sun than at other times. If Earth were upright as it revolved around the Sun, each point on Earth would have exactly 12 hours of light and 12 hours of dark each day. Because Earth is tilted, however, the northern hemisphere sometimes points toward the Sun and sometimes points away from the Sun. This tilt is responsible for the seasons. When the northern hemisphere points toward the Sun, the northernmost regions of Earth see the Sun 24 hours a day. The whole northern hemisphere gets more sunlight and gets it at a more direct angle than the southern hemisphere does during this period, which lasts for half of the year. The second half of this period, when the northern hemisphere points most directly at the Sun, is the northern hemisphere's summer, which corresponds to winter in the southern hemisphere. During the other half of the year, the southern hemisphere points more directly toward the Sun, so it is spring and summer in the southern hemisphere and fall and winter in the northern hemisphere.

Phases of the Moon

One revolution of the Moon around Earth takes a little over 27 days 7 hours. The Moon rotates on its axis in this same period of time, so the same face of the Moon is always presented to Earth. Over a period a little longer than 29 days 12 hours, the Moon goes through a series of phases, in which the amount of the lighted half of the Moon we see from Earth changes. These phases are caused by the changing angle of sunlight hitting the Moon. (The period of phases is longer than the period of revolution of the Moon, because the motion of Earth around the Sun changes the angle at which the Sun’s light hits the Moon from night to night.)

The Moon’s orbit around Earth is tilted 5° from the plane of Earth’s orbit. Because of this tilt, when the Moon is at the point in its orbit when it is between Earth and the Sun, the Moon is usually a little above or below the Sun. At that time, the Sun lights the side of the Moon facing away from Earth, and the side of the Moon facing toward Earth is dark. This point in the Moon’s orbit corresponds to a phase of the Moon called the new moon. A quarter moon occurs when the Moon is at right angles to the line formed by the Sun and Earth. The Sun lights the side of the Moon closest to it, and half of that side is visible from Earth, forming a bright half-circle. When the Moon is on the opposite side of Earth from the Sun, the face of the Moon visible from Earth is lit, showing the full moon in the sky.

Eclipses

Because of the tilt of the Moon's orbit, the Moon usually passes above or below the Sun at new moon and above or below Earth's shadow at full moon. Sometimes, though, the full moon or new moon crosses the plane of Earth's orbit. By a coincidence of nature, even though the Moon is about 400 times smaller than the Sun, it is also about 400 times closer to Earth than the Sun is, so the Moon and Sun look almost exactly the same size from Earth. If the Moon lines up with the Sun and Earth at new moon (when the Moon is between Earth and the Sun), it blocks the Sun’s light from Earth, creating a solar eclipse. If the Moon lines up with Earth and the Sun at the full moon (when Earth is between the Moon and the Sun), Earth’s shadow covers the Moon, making a lunar eclipse.

A total solar eclipse is visible from only a small region of Earth. During a solar eclipse, the complete shadow of the Moon that falls on Earth is only about 160 km (about 100 mi) wide. As Earth, the Sun, and the Moon move, however, the Moon’s shadow sweeps out a path up to 16,000 km (10,000 mi) long. The total eclipse can only be seen from within this path. A total solar eclipse occurs about every 18 months. Off to the sides of the path of a total eclipse, a partial eclipse, in which the Sun is only partly covered, is visible. Partial eclipses are much less dramatic than total eclipses. The Moon’s orbit around Earth is slightly elliptical, or egg-shaped. The distance between Earth and the Moon varies slightly as the Moon orbits Earth. When the Moon is farther from Earth than usual, it appears smaller and may not cover the entire Sun during an eclipse. A ring, or annulus, of sunlight remains visible, making an annular eclipse. An annular solar eclipse also occurs about every 18 months. Additional partial solar eclipses are also visible from Earth in between.

At a lunar eclipse, the Moon is actually in Earth's shadow. When the Moon is completely in the shadow, the total lunar eclipse is visible from everywhere on the half of Earth from which the Moon is visible at that time. As a result, more people see total lunar eclipses than see total solar eclipses.

Meteors

In an open place on a clear dark night, streaks of light may appear in a random part of the sky about once every 10 minutes. These streaks are meteors—bits of rock—burning up in Earth's atmosphere. The bits of rock are called meteoroids, and when these bits survive Earth’s atmosphere intact and land on Earth, they are known as meteorites.

Every month or so, Earth passes through the orbit of a comet. Dust from the comet remains in the comet's orbit. When Earth passes through the band of dust, the dust and bits of rock burn up in the atmosphere, creating a meteor shower. Many more meteors are visible during a meteor shower than on an ordinary night. The most observed meteor shower is the Perseid shower (see Perseids), which occurs each year on August 11th or 12th.

Mapping the Sky

Humans have picked out landmarks in the sky and mapped the heavens for thousands of years. Maps of the sky helped people navigate, measure time, and track celestial events. Now astronomers methodically map the sky to produce a universal format for the addresses of stars, galaxies, and other objects of interest.

The Constellations

Some of the stars in the sky are brighter and more noticeable than others are, and some of these bright stars appear to the eye to be grouped together. Ancient civilizations imagined that groups of stars represented figures in the sky. The oldest known representations of these groups of stars, called constellations, are from ancient Sumer (now Iraq) from about 4000 bc. The constellations recorded by ancient Greeks and Chinese resemble the Sumerian constellations. The northern hemisphere constellations that astronomers recognize today are based on the Greek constellations. Explorers and astronomers developed and recorded the official constellations of the southern hemisphere in the 16th and 17th centuries. The International Astronomical Union (IAU) officially recognizes 88 constellations. The IAU defined the boundaries of each constellation, so the 88 constellations divide the sky without overlapping.

A familiar group of stars in the northern hemisphere is called the Big Dipper. The Big Dipper is actually part of an official constellation—Ursa Major, or the Great Bear. Groups of stars that are not official constellations, such as the Big Dipper, are called asterisms. While the stars in the Big Dipper appear in approximately the same part of the sky, they vary greatly in their distance from Earth. This is true for the stars in all constellations or asterisms—the stars making up the group do not really occur close to each other in space; they merely appear together as seen from Earth. The patterns of the constellations are figments of humans’ imagination, and different artists may connect the stars of a constellation in different ways, even when illustrating the same myth.

Coordinate Systems

Astronomers use coordinate systems to label the positions of objects in the sky, just as geographers use longitude and latitude to label the positions of objects on Earth. Astronomers use several different coordinate systems. The two most widely used are the altazimuth system and the equatorial system. The altazimuth system gives an object’s coordinates with respect to the sky visible above the observer. The equatorial coordinate system designates an object’s location with respect to Earth’s entire night sky, or the celestial sphere.

C2a

Altazimuth System

One of the ways astronomers give the position of a celestial object is by specifying its altitude and its azimuth. This coordinate system is called the altazimuth system. The altitude of an object is equal to its angle, in degrees, above the horizon. An object at the horizon would have an altitude of 0°, and an object directly overhead would have an altitude of 90°. The azimuth of an object is equal to its angle in the horizontal direction, with north at 0°, east at 90°, south at 180°, and west at 270°. For example, if an astronomer were looking for an object at 23° altitude and 87° azimuth, the astronomer would know to look fairly low in the sky and almost directly east.

As Earth rotates, astronomical objects appear to rise and set, so their altitudes and azimuths are constantly changing. An object’s altitude and azimuth also vary according to an observer’s location on Earth. Therefore, astronomers almost never use altazimuth coordinates to record an object’s position. Instead, astronomers with altazimuth telescopes translate coordinates from equatorial coordinates to find an object. Telescopes that use an altazimuth mounting system may be simple to set up, but they require many calculated movements to keep them pointed at an object as it moves across the sky. These telescopes fell out of use with the development of the equatorial coordinate and mounting system in the early 1800s. However, computers have made the return to popularity possible for altazimuth systems. Altazimuth mounting systems are simple and inexpensive, and—with computers to do the required calculations and control the motor that moves the telescope—they are practical.

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Equatorial System

The equatorial coordinate system is a coordinate system fixed on the sky. In this system, a star keeps the same coordinates no matter what the time is or where the observer is located. The equatorial coordinate system is based on the celestial sphere. The celestial sphere is a giant imaginary globe surrounding Earth. This sphere has north and south celestial poles directly above Earth’s North and South poles. It has a celestial equator, directly above Earth’s equator. Another important part of the celestial sphere is the line that marks the movement of the Sun with respect to the stars throughout the year. This path is called the ecliptic. Because Earth is tilted with respect to its orbit around the Sun, the ecliptic is not the same as the celestial equator. The ecliptic is tilted 23.5° to the celestial equator and crosses the celestial equator at two points on opposite sides of the celestial sphere. The crossing points are called the vernal (or spring) equinox and the autumnal equinox. The vernal equinox and autumnal equinox mark the beginning of spring and fall, respectively. The points at which the ecliptic and celestial equator are farthest apart are called the summer solstice and the winter solstice, which mark the beginning of summer and winter, respectively.

As Earth rotates on its axis each day, the stars and other distant astronomical objects appear to rise in the eastern part of the sky and set in the west. They seem to travel in circles around Earth’s North or South poles. In the equatorial coordinate system, the celestial sphere turns with the stars (but this movement is really caused by the rotation of Earth). The celestial sphere makes one complete rotation every 23 hours 56 minutes, which is four minutes shorter than a day measured by the movement of the Sun. A complete rotation of the celestial sphere is called a sidereal day. Because the sidereal day is slightly shorter than a solar day, the stars that an observer sees from any location on Earth change slightly from night to night. The difference between a sidereal day and a solar day occurs because of Earth’s motion around the Sun.

The equivalent of longitude on the celestial sphere is called right ascension and the equivalent of latitude is declination. Specifying the right ascension of a star is equivalent to measuring the east-west distance from a line called the prime meridian that runs through Greenwich, England, for a place on Earth. Right ascension starts at the vernal equinox. Longitude on Earth is given in degrees, but right ascension is given in units of time—hours, minutes, and seconds. This is because the celestial equator is divided into 24 equal parts—each called an hour of right ascension instead of 15°. Each hour is made up of 60 minutes, each of which is equal to 60 seconds. Measuring right ascension in units of time makes determining when will be the best time for observing an object easier for astronomers. A particular line of right ascension will be at its highest point in the sky above a particular place on Earth four minutes earlier each day, so keeping track of the movement of the celestial sphere with an ordinary clock would be complicated. Astronomers have special clocks that keep sidereal time (24 sidereal hours are equal to 23 hours 56 minutes of familiar solar time). Astronomers compare the current sidereal time to the right ascension of the object they wish to view. The object will be highest in the sky when the sidereal time equals the right ascension of the object.

The direction perpendicular to right ascension—and the equivalent to latitude on Earth—is declination. Declination is measured in degrees. These degrees are divided into arcminutes and arcseconds. One arcminute is equal to 1/60 of a degree, and one arcsecond is equal to 1/60 of an arcminute, or 1/360 of a degree. The celestial equator is at declination 0°, the north celestial pole is at declination 90°, and the south celestial pole has a declination of –90°. Each star has a right ascension and a declination that mark its position in the sky. The brightest star, Sirius, for example, has right ascension 6 hours 45 minutes (abbreviated as 6h 45m) and declination -16 degrees 43 arcminutes (written –16° 43').

Stars are so far away from Earth that the main star motion we see results from Earth’s rotation. Stars do move in space, however, and these proper motions slightly change the coordinates of the nearest stars over time. The effects of the Sun and the Moon on Earth also cause slight changes in Earth’s axis of rotation. These changes, called precession, cause a slow drift in right ascension and declination. To account for precession, astronomers redefine the celestial coordinates every 50 years or so.

THE SOLAR SYSTEM

Solar systems, both our own and those located around other stars, are a major area of research for astronomers. A solar system consists of a central star orbited by planets or smaller rocky bodies. The gravitational force of the star holds the system together. In our solar system, the central star is the Sun. It holds all the planets, including Earth, in their orbits and provides light and energy necessary for life. Our solar system is just one of many. Astronomers are just beginning to be able to study other solar systems. See also Extrasolar Planets.

Objects in Our Solar System

Our solar system contains the Sun, planets (of which Earth is third from the Sun), and the planets’ satellites. It also contains asteroids, comets, and interplanetary dust and gas.

Planets and Their Satellites

Until the end of the 18th century, humans knew of five planets—Mercury, Venus, Mars, Jupiter, and Saturn—in addition to Earth. When viewed without a telescope, planets appear to be dots of light in the sky. They shine steadily, while stars seem to twinkle. Twinkling results from turbulence in Earth's atmosphere. Stars are so far away that they appear as tiny points of light. A moment of turbulence can change that light for a fraction of a second. Even though they look the same size as stars to unaided human eyes, planets are close enough that they take up more space in the sky than stars do. The disks of planets are big enough to average out variations in light caused by turbulence and therefore do not twinkle.

Between 1781 and 1930, astronomers found three more planets—Uranus, Neptune, and Pluto. This brought the total number of planets in our solar system to nine. However, in 2006 the International Astronomical Union (IAU)—the official body that names objects in the solar system—reclassified Pluto as a dwarf planet. The IAU rulings reduced the number of official planets in the solar system to eight. In order of increasing distance from the Sun, the planets in our solar system are Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, and Neptune.

Astronomers call the inner planets—Mercury, Venus, Earth, and Mars—the terrestrial planets. Terrestrial (from the Latin word terra, meaning “Earth”) planets are Earthlike in that they have solid, rocky surfaces. The next group of planets—Jupiter, Saturn, Uranus, and Neptune—is called the Jovian planets, or the giant planets. The word Jovian has the same Latin root as the word Jupiter. Astronomers call these planets the Jovian planets because they resemble Jupiter in that they are giant, massive planets made almost entirely of gas. The mass of Jupiter, for example, is 318 times the mass of Earth. The Jovian planets have no solid surfaces, although they probably have rocky cores several times more massive than Earth. Rings of chunks of ice and rock surround each of the Jovian planets. The rings around Saturn are the most familiar. See also Planetary Science.

Pluto is tiny, with a mass about one five-hundredth the mass of Earth. Pluto seems out of place, with its tiny, solid body out beyond the giant planets. Many astronomers believe that Pluto is just one of a group of icy objects in the outer solar system. These objects orbit in a part of the solar system called the Kuiper Belt. In 2006 the International Astronomical Union (IAU) reclassified Pluto as a dwarf planet because it had a rounded shape from effects of its own gravity but it was not massive enough to have cleared the region of its orbit of other bodies. Other dwarf planets in the solar system include Eris, an icy body slightly larger than Pluto that also orbits in part of the Kuiper Belt, and Ceres, a rocky body that orbits in the asteroid belt.

Most of the planets have moons, or satellites. Earth’s Moon has a diameter about one-fourth the diameter of Earth. Mars has two tiny chunks of rock, Phobos and Deimos, each only about 10 km (about 6 mi) across. Jupiter has more than 60 satellites. The largest four, known as the Galilean satellites, are Io, Europa, Ganymede, and Callisto. Ganymede is even larger than the planet Mercury. Saturn has more than 50 satellites. Saturn’s largest moon, Titan, is also larger than the planet Mercury and is enshrouded by a thick, opaque, smoggy atmosphere. Uranus has nearly 30 known moons, and Neptune has at least 13 moons. Some of the dwarf planets also have satellites. Pluto has three moons; the largest is called Charon. Charon is more than half as big as Pluto. Eris has a small moon named Dysnomia.

Comets and Asteroids

Comets and asteroids are rocky and icy bodies that are smaller than planets. The distinction between comets, asteroids, and other small bodies in the solar system is a little fuzzy, but generally a comet is icier than an asteroid and has a more elongated orbit. The orbit of a comet takes it close to the Sun, then back into the outer solar system. When comets near the Sun, some of their ice turns from solid material into gas, releasing some of their dust. Comets have long tails of glowing gas and dust when they are near the Sun. Asteroids are rockier bodies and usually have orbits that keep them at always about the same distance from the Sun.

Both comets and asteroids have their origins in the early solar system. While the solar system was forming, many small, rocky objects called planetesimals condensed from the gas and dust of the early solar system. Millions of planetesimals remain in orbit around the Sun. A large spherical cloud of such objects out beyond Pluto forms the Oort cloud. The objects in the Oort cloud are considered comets. When our solar system passes close to another star or drifts closer than usual to the center of our galaxy, the change in gravitational pull may disturb the orbit of one of the icy comets in the Oort cloud. As this comet falls toward the Sun, the ice turns into vapor, freeing dust from the object. The gas and dust form the tail or tails of the comet. The gravitational pull of large planets such as Jupiter or Saturn may swerve the comet into an orbit closer to the Sun. The time needed for a comet to make a complete orbit around the Sun is called the comet’s period. Astronomers believe that comets with periods longer than about 200 years come from the Oort Cloud. Short-period comets, those with periods less than about 200 years, probably come from the Kuiper Belt, a ring of planetesimals beyond Neptune. The material in comets is probably from the very early solar system, so astronomers study comets to find out more about our solar system’s formation.

When the solar system was forming, some of the planetesimals came together more toward the center of the solar system. Gravitational forces from the giant planet Jupiter prevented these planetesimals from forming full-fledged planets. Instead, the planetesimals broke up to create thousands of minor planets, or asteroids, that orbit the Sun. Most of them are in the asteroid belt, between the orbits of Mars and Jupiter, but thousands are in orbits that come closer to Earth or even cross Earth's orbit. Scientists are increasingly aware of potential catastrophes if any of the largest of these asteroids hits Earth. Perhaps 2,000 asteroids larger than 1 km (0.6 mi) in diameter are potential hazards.

The Sun

The Sun is the nearest star to Earth and is the center of the solar system. It is only 8 light-minutes away from Earth, meaning light takes only eight minutes to travel from the Sun to Earth. The next nearest star is 4 light-years away, so light from this star, Proxima Centauri (part of the triple star Alpha Centauri), takes four years to reach Earth. The Sun's closeness means that the light and other energy we get from the Sun dominate Earth’s environment and life. The Sun also provides a way for astronomers to study stars. They can see details and layers of the Sun that are impossible to see on more distant stars. In addition, the Sun provides a laboratory for studying hot gases held in place by magnetic fields. Scientists would like to create similar conditions (hot gases contained by magnetic fields) on Earth. Creating such environments could be useful for studying basic physics.

The Sun produces its energy by fusing hydrogen into helium in a process called nuclear fusion. In nuclear fusion, two atoms merge to form a heavier atom and release energy (see Nuclear Energy: Nuclear Fusion). The Sun and stars of similar mass start off with enough hydrogen to shine for about 10 billion years. The Sun is less than halfway through its lifetime.

Studying the Solar System

Although most telescopes are used mainly to collect the light of faint objects so that they can be studied, telescopes for planetary and other solar system studies are also used to magnify images. Astronomers use some of the observing time of several important telescopes for planetary studies. In general, planetary astronomers must apply and compete for observing time on telescopes with astronomers seeking to study other objects. Some planetary objects can be studied as they pass in front of, or occult, distant stars. The atmosphere of Neptune's moon Triton and the shapes of asteroids can be investigated in this way, for example. The fields of radio and infrared astronomy are useful for measuring the temperatures of planets and satellites. Ultraviolet astronomy can help astronomers study the magnetic fields of planets.

During the space age, scientists have developed telescopes and other devices, such as instruments to measure magnetic fields or space dust, that can leave Earth's surface and travel close to other objects in the solar system. Robotic spacecraft have visited all of the planets in the solar system except Pluto. Some missions have targeted specific planets and spent much time studying a single planet, and some spacecraft have flown past a number of planets.

Astronomers use different telescopes to study the Sun than they use for nighttime studies because of the extreme brightness of the Sun. Telescopes in space, such as the Solar and Heliospheric Observatory (SOHO) and the Transition Region and Coronal Explorer (TRACE), are able to study the Sun in regions of the spectrum other than visible light. X rays, ultraviolet, and radio waves from the Sun are especially interesting to astronomers. Studies in various parts of the spectrum give insight into giant flows of gas in the Sun, into how the Sun's energy leaves the Sun to travel to Earth, and into what the interior of the Sun is like. Astronomers also study solar-terrestrial relations—the relation of activity on the Sun with magnetic storms and other effects on Earth. Some of these storms and effects can affect radio reception, cause electrical blackouts, or damage satellites in orbit.

Solar System Formation

Our solar system began forming about 5 billion years ago, when a cloud of gas and dust between the stars in our Milky Way Galaxy began contracting. A nearby supernova—an exploding star—may have started the contraction, but most astronomers believe a random change in density in the cloud caused the contraction. Once the cloud—known as the solar nebula—began to contract, the contraction occurred faster and faster. The gravitational energy caused by this contraction heated the solar nebula. As the cloud became smaller, it began to spin faster, much as a spinning skater will spin faster by pulling in his or her arms. This spin kept the nebula from forming a sphere; instead, it settled into a disk of gas and dust.

In this disk, small regions of gas and dust began to draw closer and stick together. The objects that resulted, which were usually less than 500 km (300 mi) across, are the planetesimals. Eventually, some planetesimals stuck together and grew to form the planets. Scientists have made computer models of how they believe the early solar system behaved. The models show that for a solar system to produce one or two huge planets like Jupiter and several other, much smaller planets is not unusual.

The largest region of gas and dust wound up in the center of the nebula and formed the protosun (proto is Greek for “before” and is used to distinguish between an object and its forerunner). The increasing temperature and pressure in the middle of the protosun vaporized the dust and eventually allowed nuclear fusion to begin, marking the formation of the Sun. The young Sun gave off a strong solar wind that drove off most of the lighter elements, such as hydrogen and helium, from the inner planets. The inner planets then solidified and formed rocky surfaces. The solar wind lost strength. Jupiter’s gravitational pull was strong enough to keep its shroud of hydrogen and helium gas. Saturn, Uranus, and Neptune also kept their layers of light gases.

The theory of solar system formation described above accounts for the appearance of the solar system as we know it. Examples of this appearance include the fact that the planets all orbit the Sun in the same direction and that almost all the planets rotate on their axes in the same direction. The recent discoveries of distant solar systems with different properties could lead to modifications in the theory, however.

Studies in the visible, the infrared, and the shortest radio wavelengths have revealed disks around several young stars in our galaxy. One such object, Beta Pictoris (about 62 light-years from Earth), has revealed a warp in the disk that could be a sign of planets in orbit. Astronomers are hopeful that, in the cases of these young stars, they are studying the early stages of solar system formation.

Detecting Other Solar Systems

Although astronomers have long assumed that many other stars have planets, they have been unable to detect these other solar systems until recently. Planets orbiting around stars other than the Sun are called extrasolar planets. Planets are small and dim compared to stars, so they are lost in the glare of their parent stars and are invisible to direct observation with telescopes.

Astronomers have tried to detect other solar systems by searching for the way a planet affects the movement of its parent star. The gravitational attraction between a planet and its star pulls the star slightly toward the planet, so the star wobbles slightly as the planet orbits it. Throughout the mid- and late 1900s, several observatories tried to detect wobbles in the nearest stars by watching the stars’ movement across the sky. Wobbles were reported in several stars, but later observations showed that the results were false.

In the early 1990s, studies of a pulsar revealed at least two planets orbiting it. Pulsars are compact stars that give off pulses of radio waves at very regular intervals. The pulsar, designated PSR 1257+12, is about 1,000 light-years from Earth. This pulsar's pulses sometimes came a little early and sometimes a little late in a periodic pattern, revealing that an unseen object was pulling the pulsar toward and away from Earth. The environment of a pulsar, which emits X rays and other strong radiation that would be harmful to life on Earth, is so extreme that these objects would have little resemblance to planets in our solar system.

The wobbling of a star changes the star’s light that reaches Earth. When the star moves away from Earth, even slightly, each wave of light must travel farther to Earth than the wave before it. This increases the distance between waves (called the wavelength) as the waves reach Earth. When a star’s planet pulls the star closer to Earth, each successive wavefront has less distance to travel to reach Earth. This shortens the wavelength of the light that reaches Earth. This effect is called the Doppler effect. No star moves fast enough for the change in wavelength to result in a noticeable change in color, which depends on wavelength, but the changes in wavelength can be measured with precise instruments. Because the planet’s effect on the star is very small, astronomers must analyze the starlight carefully to detect a shift in wavelength. They do this by first using a technique called spectroscopy to separate the white starlight into its component colors, as water vapor does to sunlight in a rainbow. Stars emit light in a continuous range. The range of wavelengths a star emits is called the star’s spectrum. This spectrum has dark lines, called absorption lines, at wavelengths at which atoms in the outermost layers of the star absorb light.

Astronomers know what the exact wavelength of each absorption line is for a star that is not moving. By seeing how far the movement of a star shifts the absorption lines in its spectrum, astronomers can calculate how fast the star is moving. If the motion fits the model of the effect of a planet, astronomers can calculate the mass of the planet and how close it is to the star. These calculations can only provide the lower limit to the planet’s mass, because it is impossible for astronomers to tell at what angle the planet orbits the star. Astronomers need to know the angle at which the planet orbits the star to calculate the planet’s mass accurately. Because of this uncertainty, some of the giant extrasolar planets may actually be a type of failed star called a brown dwarf instead of planets. Most astronomers believe that many of the suspected planets are true planets.

Since 1995 astronomers have discovered more than 160 extrasolar planets. Astronomers now know of far more planets outside our solar system than inside our solar system. Most of these planets, surprisingly, are more massive than Jupiter and are orbiting so close to their parent stars that some of them have years (the time it takes to orbit the parent star once) as long as only a few days on Earth. These solar systems are so different from our solar system that astronomers are still trying to reconcile them with the current theory of solar system formation. Some astronomers suggest that the giant extrasolar planets formed much farther away from their stars and were later thrown into the inner solar systems by some gravitational interaction.

STARS

Stars are an important topic of astronomical research. Stars are balls of gas that shine or used to shine because of nuclear fusion in their cores. The most familiar star is the Sun. The nuclear fusion in stars produces a force that pushes the material in a star outward. However, the gravitational attraction of the star’s material for itself pulls the material inward. A star can remain stable as long as the outward pressure and gravitational force balance. The properties of a star depend on its mass, its temperature, and its stage in evolution.

Astronomers study stars by measuring their brightness or, with more difficulty, their distances from Earth. They measure the “color” of a star—the differences in the star’s brightness from one part of the spectrum to another—to determine its temperature. They also study the spectrum of a star’s light to determine not only the temperature, but also the chemical makeup of the star’s outer layers.

Kinds of Stars

Many different types of stars exist. Some types of stars are really just different stages of a star’s evolution. Some types are different because the stars formed with much more or much less mass than other stars, or because they formed close to other stars. The Sun is a type of star known as a main-sequence star. Eventually, main-sequence stars such as the Sun swell into giant stars and then evolve into tiny, dense, white dwarf stars. Main-sequence stars and giants have a role in the behavior of most variable stars and novas. A star much more massive than the Sun will become a supergiant star, then explode as a supernova. A supernova may leave behind a neutron star or a black hole.

In about 1910 Danish astronomer Ejnar Hertzsprung and American astronomer Henry Norris Russell independently worked out a way to graph basic properties of stars. On the horizontal axis of their graphs, they plotted the temperatures of stars. On the vertical axis, they plotted the brightness of stars in a way that allowed the stars to be compared. (One plotted the absolute brightness, or absolute magnitude, of a star, a measurement of brightness that takes into account the distance of the star from Earth. The other plotted stars in a nearby galaxy, all about the same distance from Earth.) The resulting Hertzsprung-Russell diagram, also called an H-R diagram or a color-magnitude diagram (where color relates to temperature), is a basic tool of astronomers.

Main-Sequence Stars

On an H-R diagram, the brightest stars are at the top and the hottest stars are at the left. Hertzsprung and Russell found that most stars fell on a diagonal line across the H-R diagram from upper left to lower right. This line is called the main sequence. The diagonal line of main-sequence stars indicates that temperature and brightness of these stars are directly related. The hotter a main-sequence star is, the brighter it is. The Sun is a main-sequence star, located in about the middle of the graph. More faint, cool stars exist than hot, bright ones, so the Sun is brighter and hotter than most of the stars in the universe.

Giant and Supergiant Stars

At the upper right of the H-R diagram, above the main sequence, stars are brighter than main-sequence stars of the same color. The only way stars of a certain color can be brighter than other stars of the same color is if the brighter stars are also bigger. Bigger stars are not necessarily more massive, but they do have larger diameters. Stars that fall in the upper right of the H-R diagram are known as giant stars or, for even brighter stars, supergiant stars. Supergiant stars have both larger diameters and larger masses than giant stars.

Giant and supergiant stars represent stages in the lives of stars after they have burned most of their internal hydrogen fuel. Stars swell as they move off the main sequence, becoming giants and—for more massive stars—supergiants.

White Dwarf Stars

A few stars fall in the lower left portion of the H-R diagram, below the main sequence. Just as giant stars are larger and brighter than main-sequences stars, these stars are smaller and dimmer. These smaller, dimmer stars are hot enough to be white or blue-white in color and are known as white dwarfs.

White dwarf stars are only about the size of Earth. They represent stars with about the mass of the Sun that have burned as much hydrogen as they can. The gravitational force of a white dwarf’s mass is pulling the star inward, but electrons in the star resist being pushed together. The gravitational force is able to pull the star into a much denser form than it was in when the star was burning hydrogen. The final stage of life for all stars like the Sun is the white dwarf stage.

Variable Stars

Many stars vary in brightness over time. These variable stars come in a variety of types. One important type is called a Cepheid variable, named after the star delta Cephei, which is a prime example of a Cepheid variable. These stars vary in brightness as they swell and contract over a period of weeks or months. Their average brightness depends on how long the period of variation takes. Thus astronomers can determine how bright the star is merely by measuring the length of the period. By comparing how intrinsically bright these variable stars are with how bright they look from Earth, astronomers can calculate how far away these stars are from Earth. Since they are giant stars and are very bright, Cepheid variables in other galaxies are visible from Earth. Studies of Cepheid variables tell astronomers how far away these galaxies are and are very useful for determining the distance scale of the universe. The Hubble Space Telescope (HST) can determine the periods of Cepheid stars in galaxies farther away than ground-based telescopes can see. Astronomers are developing a more accurate idea of the distance scale of the universe with HST data.

Cepheid variables are only one type of variable star. Stars called long-period variables vary in brightness as they contract and expand, but these stars are not as regular as Cepheid variables. Mira, a star in the constellation Cetus (the whale), is a prime example of a long-period variable star. Variable stars called eclipsing binary stars are really pairs of stars. Their brightness varies because one member of the pair appears to pass in front of the other, as seen from Earth. A type of variable star called R Coronae Borealis stars varies because they occasionally give off clouds of carbon dust that dim these stars.

Novas

Sometimes stars brighten drastically, becoming as much as 100 times brighter than they were. These stars are called novas (Latin for 'new stars'). They are not really new, just much brighter than they were earlier. A nova is a binary, or double, star in which one member is a white dwarf and the other is a giant or supergiant. Matter from the large star falls onto the small star. After a thick layer of the large star’s atmosphere has collected on the white dwarf, the layer burns off in a nuclear fusion reaction. The fusion produces a huge amount of energy, which, from Earth, appears as the brightening of the nova. The nova gradually returns to its original state, and material from the large star again begins to collect on the white dwarf.

Supernovas

Sometimes stars brighten many times more drastically than novas do. A star that had been too dim to see can become one of the brightest stars in the sky. These stars are called supernovas. Sometimes supernovas that occur in other galaxies are so bright that, from Earth, they appear as bright as their host galaxy.

There are two types of supernova. One type is an extreme case of a nova, in which matter falls from a giant or supergiant companion onto a white dwarf. In the case of a supernova, the white dwarf gains so much fuel from its companion that the star increases in mass until strong gravitational forces cause it to become unstable. The star collapses and the core explodes, vaporizing much of the white dwarf and producing an immense amount of light. Only bits of the white dwarf remain after this type of supernova occurs.

The other type of supernova occurs when a supergiant star uses up all its nuclear fuel in nuclear fusion reactions. The star uses up its hydrogen fuel, but the core is hot enough that it provides the initial energy necessary for the star to begin “burning” helium, then carbon, and then heavier elements through nuclear fusion. The process stops when the core is mostly iron, which is too heavy for the star to “burn” in a way that gives off energy. With no such fuel left, the inward gravitational attraction of the star’s material for itself has no outward balancing force, and the core collapses. As it collapses, the core releases a shock wave that tears apart the star’s atmosphere. The core continues collapsing until it forms either a neutron star or a black hole, depending on its mass.

Only a handful of supernovas are known in our galaxy. The last Milky Way supernova seen from Earth was observed in 1604. In 1987 astronomers observed a supernova in the Large Magellanic Cloud, one of the Milky Way’s satellite galaxies (see Magellanic Clouds). This supernova became bright enough to be visible to the unaided eye and is still under careful study from telescopes on Earth and from the Hubble Space Telescope. A supernova in the process of exploding emits radiation in the X-ray range and ultraviolet and radio radiation studies in this part of the spectrum are especially useful for astronomers studying supernova remnants.

Neutron Stars and Pulsars

Neutron stars are the collapsed cores sometimes left behind by supernova explosions. Pulsars are a special type of neutron star. Pulsars and neutron stars form when the remnant of a star left after a supernova explosion collapses until it is about 10 km (about 6 mi) in radius. At that point, the neutrons—electrically neutral atomic particles—of the star resist being pressed together further. When the force produced by the neutrons balances the gravitational force, the core stops collapsing. At that point, the star is so dense that a teaspoonful has the mass of a billion metric tons.

Neutron stars become pulsars when the magnetic field of a neutron star directs a beam of radio waves out into space. The star is so small that it rotates from one to a few hundred times per second. As the star rotates, the beam of radio waves sweeps out a path in space. If Earth is in the path of the beam, radio astronomers see the rotating beam as periodic pulses of radio waves. This pulsing is the reason these stars are called pulsars.

Some neutron stars are in binary systems with an ordinary star neighbor. The gravitational pull of a neutron star pulls material off its neighbor. The rotation of the neutron star heats the material, causing it to emit X rays. The neutron star’s magnetic field directs the X rays into a beam that sweeps into space and may be detected from Earth. Astronomers call these stars X-ray pulsars.

Gamma-ray spacecraft detect bursts of gamma rays about once a day. The bursts come from sources in distant galaxies, so they must be extremely powerful for us to be able to detect them. A leading model used to explain the bursts is the merger of two neutron stars in a distant galaxy with a resulting hot fireball. A few such explosions have been seen and studied with the Hubble and Keck telescopes.

Black Holes

Black holes are objects that are so massive and dense that their immense gravitational pull does not even let light escape. If the core left over after a supernova explosion has a mass of more than about five times that of the Sun, the force holding up the neutrons in the core is not large enough to balance the inward gravitational force. No outward force is large enough to resist the gravitational force. The core of the star continues to collapse. When the core's mass is sufficiently concentrated, the gravitational force of the core is so strong that nothing, not even light, can escape it. The gravitational force is so strong that classical physics no longer applies, and astronomers use Einstein’s general theory of relativity to explain the behavior of light and matter under such strong gravitational forces. According to general relativity, space around the core becomes so warped that nothing can escape, creating a black hole. A star with a mass ten times the mass of the Sun would become a black hole if it were compressed to 90 km (60 mi) or less in diameter.

Astronomers have various ways of detecting black holes. When a black hole is in a binary system, matter from the companion star spirals into the black hole, forming a disk of gas around it. The disk becomes so hot that it gives off X rays that astronomers can detect from Earth. Astronomers use X-ray telescopes in space to find X-ray sources, and then they look for signs that an unseen object of more than about five times the mass of the Sun is causing gravitational tugs on a visible object.

Star Locations

The basic method that astronomers use to find the distance of a star from Earth uses parallax. Parallax is the change in apparent position of a distant object when viewed from different places. For example, imagine a tree standing in the center of a field, with a row of buildings at the edge of the field behind the tree. If two observers stand at the two front corners of the field, the tree will appear in front of a different building for each observer. Similarly, a nearby star's position appears slightly different when seen from different angles.

Parallax also allows human eyes to judge distance. Each eye sees an object from a slightly different angle. The brain compares the two pictures to judge the distance to the object. Astronomers use the same idea to calculate the distance to a star. Stars are very far away, so astronomers must look at a star from two locations as far apart as possible to get a measurement. The movement of Earth around the Sun makes this possible. By taking measurements six months apart from the same place on Earth, astronomers take measurements from locations separated by the diameter of Earth’s orbit. That is a separation of about 300 million km (186 million mi). The nearest stars will appear to shift slightly with respect to the background of more distant stars. Even so, the greatest stellar parallax is only about 0.77 seconds of arc, an amount 4,600 times smaller than a single degree. Astronomers calculate a star’s distance by dividing 1 by the parallax. Distances of stars are usually measured in parsecs. A parsec is 3.26 light-years, and a light-year is the distance that light travels in a year, or about 9.5 trillion km (5.9 trillion mi). Proxima Centauri, the Sun’s nearest neighbor, has a parallax of 0.77 seconds of arc. This measurement indicates that Proxima Centauri’s distance from Earth is about 1.3 parsecs, or 4.2 light-years. Because Proxima Centauri is the Sun’s nearest neighbor, it has a larger parallax than any other star.

Astronomers can measure stellar parallaxes for stars up to about 500 light-years away, which is only about 2 percent of the distance to the center of our galaxy. Beyond that distance, the parallax angle is too small to measure.

A European Space Agency spacecraft named Hipparcos (an acronym for High Precision Parallax Collecting Satellite), launched in 1989, gave a set of accurate parallaxes across the sky that was released in 1997. This set of measurements has provided a uniform database of stellar distances for over 100,000 stars and a somewhat less accurate database of over 1 million stars. These parallax measurements provide the base for measurements of the distance scale of the universe. Hipparcos data are leading to more accurate age calculations for the universe and for objects in it, especially globular clusters of stars.

Starlight

Astronomers use a star’s light to determine the star’s temperature, composition, and motion. Astronomers analyze a star’s light by looking at its intensity at different wavelengths. Blue light has the shortest visible wavelengths, at about 400 nanometers. (A nanometer, abbreviated nm, is one billionth of a meter, or about one forty-thousandth of an inch.) Red light has the longest visible wavelengths, at about 650 nm. A law of radiation known as Wien's displacement law (developed by German physicist Wilhelm Wien) links the wavelength at which the most energy is given out by an object and its temperature. A star like the Sun, whose surface temperature is about 6000 K (about 5730°C or about 10,350°F), gives off the most radiation in yellow-green wavelengths, with decreasing amounts in shorter and longer wavelengths. Astronomers put filters of different standard colors on telescopes to allow only light of a particular color from a star to pass. In this way, astronomers determine the brightness of a star at particular wavelengths. From this information, astronomers can use Wien’s law to determine the star’s surface temperature.

Astronomers can see the different wavelengths of light of a star in more detail by looking at its spectrum. The continuous rainbow of color of a star's spectrum is crossed by dark lines, or spectral lines. In the early 19th century, German physicist Josef Fraunhofer identified such lines in the Sun's spectrum, and they are still known as Fraunhofer lines. American astronomer Annie Jump Cannon divided stars into several categories by the appearance of their spectra. She labeled them with capital letters according to how dark their hydrogen spectral lines were. Later astronomers reordered these categories according to decreasing temperature. The categories are O, B, A, F, G, K, and M, where O stars are the hottest and M stars are the coolest. The Sun is a G star. An additional spectral type, L stars, was suggested in 1998 to accommodate some cool stars studied using new infrared observational capabilities. Detailed study of spectral lines shows the physical conditions in the atmospheres of stars. Careful study of spectral lines shows that some stars have broader lines than others of the same spectral type. The broad lines indicate that the outer layers of these stars are more diffuse, meaning that these layers are larger, but spread more thinly, than the outer layers of other stars. Stars with large diffuse atmospheres are called giants. Giant stars are not necessarily more massive than other stars—the outer layers of giant stars are just more spread out.

Many stars have thousands of spectral lines from iron and other elements near iron in the periodic table. Other stars of the same temperature have relatively few spectral lines from such elements. Astronomers interpret these findings to mean that two different populations of stars exist. Some formed long ago, before supernovas produced the heavy elements, and others formed more recently and incorporated some heavy elements. The Sun is one of the more recent stars.

Spectral lines can also be studied to see if they change in wavelength or are different in wavelength from sources of the same lines on Earth. These studies tell us, according to the Doppler effect, how much the star is moving toward or away from us. Such studies of starlight can tell us about the orbits of stars in binary systems or about the pulsations of variable stars, for example.

VII

GALAXIES

Astronomers study galaxies to learn about the structure of the universe. Galaxies are huge collections of billions of stars. Our Sun is part of the Milky Way Galaxy. Galaxies also contain dark strips of dust and may contain huge black holes at their centers. Galaxies exist in different shapes and sizes. Some galaxies are spirals, some are oval, or elliptical, and some are irregular. The Milky Way is a spiral galaxy. Galaxies tend to group together in clusters.

The Milky Way

Our Sun is only one of about 400 billion stars in our home galaxy, the Milky Way. On a dark night, far from outdoor lighting, a faint, hazy, whitish band spans the sky. This band is the Milky Way Galaxy as it appears from Earth. The Milky Way looks splotchy, with darker regions interspersed with lighter ones.

The Milky Way Galaxy is a pinwheel-shaped flattened disk about 75,000 light-years in diameter. The Sun is located on a spiral arm about two-thirds of the way out from the center. The galaxy spins, but the center spins faster than the arms. At Earth’s position, the galaxy makes a complete rotation about every 200 million years.

When observers on Earth look toward the brightest part of the Milky Way, which is in the constellation Sagittarius, they look through the galaxy’s disk toward its center. This disk is composed of the stars, gas, and dust between Earth and the galactic center. When observers look in the sky in other directions, they do not see as much of the galaxy’s gas and dust, and so can see objects beyond the galaxy more clearly.

The Milky Way Galaxy has a core surrounded by its spiral arms. A spherical cloud containing about 100 examples of a type of star cluster known as a globular cluster surrounds the galaxy. Still farther out is a galactic corona. Astronomers are not sure what types of particles or objects occupy the corona, but these objects do exert a measurable gravitational force on the rest of the galaxy.

Characteristics of Galaxies

Galaxies contain billions of stars, but the space between stars is not empty. Astronomers believe that almost every galaxy probably has a huge black hole at its center.

Interstellar Matter

The space between stars in a galaxy consists of low-density gas and dust. The dust is largely carbon given off by red-giant stars. The gas is largely hydrogen, which accounts for 90 percent of the atoms in the universe. Hydrogen exists in two main forms in the universe. Astronomers give complete hydrogen atoms, with a nucleus and an electron, a designation of the Roman numeral I, or HI. Ionized hydrogen, hydrogen made up of atoms missing their electrons, is given the designation II, or HII. Clouds, or regions, of both types of hydrogen exist between the stars. HI regions are too cold to produce visible radiation, but they do emit radio waves that are useful in measuring the movement of gas in our own galaxy and in distant galaxies. The HII regions form around hot stars. These regions emit diffuse radiation in the visual range, as well as in the radio, infrared, and ultraviolet ranges. The cloudy light from such regions forms beautiful nebulas such as the Great Orion Nebula.

Astronomers have located over 100 types of molecules in interstellar space. These molecules occur only in trace amounts among the hydrogen. Still, astronomers can use these molecules to map galaxies. By measuring the density of the molecules throughout a galaxy, astronomers can get an idea of the galaxy’s structure.

Interstellar dust sometimes gathers to form dark nebulae, which appear in silhouette against background gas or stars from Earth. The Horsehead Nebula, for example, is the silhouette of interstellar dust against a background HI region. See also Interstellar Matter.

Galactic Black Holes

The first known black holes were the collapsed cores of supernova stars, but astronomers have since discovered signs of much larger black holes at the centers of galaxies. These galactic black holes contain millions of times as much mass as the Sun. Astronomers believe that huge black holes such as these provide the energy of mysterious objects called quasars. Quasars are very distant objects that are moving away from Earth at high speed. The first ones discovered were very powerful radio sources, but scientists have since discovered quasars that don’t strongly emit radio waves. Astronomers believe that almost every galaxy, whether spiral or elliptical, has a huge black hole at its center.

Astronomers look for galactic black holes by studying the movement of galaxies. By studying the spectrum of a galaxy, astronomers can tell if gas near the center of the galaxy is rotating rapidly. By measuring the speed of rotation and the distance from various points in the galaxy to the center of the galaxy, astronomers can determine the amount of mass in the center of the galaxy. Measurements of many galaxies show that gas near the center is moving so quickly that only a black hole could be dense enough to concentrate so much mass in such a small space. Astronomers suspect that a significant black hole occupies even the center of the Milky Way. The clear images from the Hubble Space Telescope have allowed measurements of motions closer to the centers of galaxies than previously possible, and have led to the confirmation in several cases that giant black holes are present.

Types of Galaxies

Galaxies are classified by shape. The three types are spiral, elliptical, and irregular. Spiral galaxies consist of a central mass with one, two, or three arms that spiral around the center. An elliptical galaxy is oval, with a bright center that gradually, evenly dims to the edges. Irregular galaxies are not symmetrical and do not look like spiral or elliptical galaxies. Irregular galaxies vary widely in appearance. A galaxy that has a regular spiral or elliptical shape but has some special oddity is known as a peculiar galaxy. For example, some peculiar galaxies are stretched and distorted from the gravitational pull of a nearby galaxy.

Spiral

Spiral galaxies are flattened pinwheels in shape. They can have from one to three spiral arms coming from a central core. The Great Andromeda Spiral Galaxy is a good example of a spiral galaxy. The shape of the Milky Way is not visible from Earth, but astronomers have measured that the Milky Way is also a spiral galaxy. American astronomer Edwin Hubble further classified spiral galaxies by the tightness of their spirals. In order of increasingly open arms, Hubble’s types are Sa, Sb, and Sc.

Some galaxies have a straight, bright, bar-shaped feature across their center, with the spiral arms coming off the bar or off a ring around the bar. With a capital B for the bar, the Hubble types of these galaxies are SBa, SBb, and SBc.

Elliptical

Many clusters of galaxies have giant elliptical galaxies at their centers. Smaller elliptical galaxies, called dwarf elliptical galaxies, are much more common than giant ones. Most of the two dozen galaxies in the Milky Way’s Local Group of galaxies are dwarf elliptical galaxies.

Astronomers classify elliptical galaxies by how oval they look, ranging from E0 for very round to E3 for intermediately oval to E7 for extremely elongated. The galaxy class E7 is also called S0, which is also known as a lenticular galaxy, a shape with an elongated disk but no spiral arms. Because astronomers can see other galaxies only from the perspective of Earth, the shape astronomers see is not necessarily the exact shape of a galaxy. For instance, they may be viewing it from an end, and not from above or below.

Irregular

Some galaxies have no structure, while others have some trace of structure but do not fit the spiral or elliptical classes. All of these galaxies are called irregular galaxies. The two small galaxies that are satellites to the Milky Way Galaxy are both irregular. They are known as the Magellanic Clouds. The Large Magellanic Cloud shows signs of having a bar in its center. The Small Magellanic Cloud is more formless. Studies of stars in the Large and Small Magellanic Clouds have been fundamental for astronomers’ understanding of the universe. Each of these galaxies provides groups of stars that are all at the same distance from Earth, allowing astronomers to compare the absolute brightness of these stars.

Movement of Galaxies

In the late 1920s American astronomer Edwin Hubble discovered that all but the nearest galaxies to us are receding, or moving away from us. Further, he found that the farther away from Earth a galaxy is, the faster it is receding. He made his discovery by taking spectra of galaxies and measuring the amount by which the wavelengths of spectral lines were shifted. He measured distance in a separate way, usually from studies of Cepheid variable stars. Hubble discovered that essentially all the spectra of all the galaxies were shifted toward the red, or had redshifts. The redshifts of galaxies increased with increasing distance from Earth. After Hubble’s work, other astronomers made the connection between redshift and velocity, showing that the farther a galaxy is from Earth, the faster it moves away from Earth. This idea is called Hubble’s law and is the basis for the belief that the universe is fairly uniformly expanding. Other uniformly expanding three-dimensional objects, such as a rising cake with raisins in the batter, also demonstrate the consequence that the more distant objects (such as the other raisins with respect to any given raisin) appear to recede more rapidly than nearer ones. This consequence is the result of the increased amount of material expanding between these more distant objects.

Hubble's law states that there is a straight-line, or linear, relationship between the speed at which an object is moving away from Earth and the distance between the object and Earth. The speed at which an object is moving away from Earth is called the object’s velocity of recession. Hubble’s law indicates that as velocity of recession increases, distance increases by the same proportion. Using this law, astronomers can calculate the distance to the most distant galaxies, given only measurements of their velocities calculated by observing how much their light is shifted. Astronomers can accurately measure the redshifts of objects so distant that the distance between Earth and the objects cannot be measured by other means.

The constant of proportionality that relates velocity to distance in Hubble's law is called Hubble's constant, or H. Hubble's law is often written v=Hd, or velocity equals Hubble's constant multiplied by distance. Thus determining Hubble's constant will give the speed of the universe's expansion. The inverse of Hubble’s constant, or 1/H, theoretically provides an estimate of the age of the universe. Astronomers now believe that Hubble’s constant has changed over the lifetime of the universe, however, so estimates of expansion and age must be adjusted accordingly.

The value of Hubble’s constant probably falls between 64 and 78 kilometers per second per megaparsec (between 40 and 48 miles per second per megaparsec). A megaparsec is 1 million parsecs and a parsec is 3.26 light-years. Astronomers used the Hubble Space Telescope to study Cepheid variables in distant galaxies to get an accurate measurement of the distance between the stars and Earth to refine the value of Hubble’s constant. The value these astronomers found was 72 kilometers per second per megaparsec (45 miles per second per megaparsec), with an uncertainty of only 10 percent.

The actual age of the universe depends not only on Hubble's constant but also on how much the gravitational pull of the mass in the universe slows the universe’s expansion. Some data from studies that use the brightness of distant supernovas to assess distance indicate that the universe's expansion is speeding up instead of slowing down. Astronomers invented the term “dark energy” for the unknown cause of this accelerating expansion and are actively investigating these topics.

VIII

THE UNIVERSE

The ultimate goal of astronomers is to understand the structure, behavior, and evolution of all of the matter and energy that exists. Astronomers call the set of all matter and energy the universe. The universe is infinite in space, but astronomers believe it does have a finite age. Astronomers accept the theory that about 14 billion years ago the universe began as an explosive event resulting in a hot, dense, expanding sea of matter and energy. This event is known as the big bang (see Big Bang Theory). Astronomers cannot observe that far back in time. Many astronomers believe, however, that within the first fraction of a second after the big bang, the universe went through a tremendous inflation, expanding many times in size, before it resumed a slower expansion (see Inflationary Theory).

As the universe expanded and cooled, various forms of elementary particles of matter formed. By the time the universe was one second old, protons had formed. For approximately the next 1,000 seconds, in the era of nucleosynthesis, all the nuclei of deuterium (hydrogen with both a proton and neutron in the nucleus) that are present in the universe today formed. During this brief period, some nuclei of lithium, beryllium, and helium formed as well.

When the universe was about 1 million years old, it had cooled to about 3000 K (about 3300°C or about 5900°F). At that temperature, the protons and heavier nuclei formed during nucleosynthesis could combine with electrons to form atoms. Before electrons combined with nuclei, the travel of radiation through space was very difficult. Radiation in the form of photons (packets of light energy) could not travel very far without colliding with electrons. Once protons and electrons combined to form hydrogen, photons became able to travel through space. The radiation carried by the photons had the characteristic spectrum of a hot gas. Since the time this radiation was first released, it has cooled and is now 3 K (-270°C or –450°F). It is called the primeval background radiation and has been definitively detected and studied, first by radio telescopes and then by the Cosmic Background Explorer (COBE) and Wilkinson Microwave Anisotropy Probe (WMAP) spacecrafts. COBE, WMAP, and ground-based radio telescopes detected tiny deviations from uniformity in the primeval background radiation; these deviations may be the seeds from which clusters of galaxies grew.

The gravitational force from invisible matter, known as dark matter, may have helped speed the formation of structure in the universe. Observations from the Hubble Space Telescope have revealed galaxies older than astronomers expected, reducing the interval between the big bang and the formation of galaxies or clusters of galaxies.

From about 2 billion years after the big bang for another 2 billion years, quasars formed as active giant black holes in the cores of galaxies. These quasars gave off radiation as they consumed matter from nearby galaxies. Few quasars appear close to Earth, so quasars must be a feature of the earlier universe.

A population of stars formed out of the interstellar gas and dust that contracted to form galaxies. This first population, known as Population II, was made up almost entirely of hydrogen and helium. The stars that formed evolved and gave out heavier elements that were made through fusion in the stars’ cores or that were formed as the stars exploded as supernovas. The later generation of stars, to which the Sun belongs, is known as Population I and contains heavy elements formed by the earlier population. The Sun formed about 5 billion years ago and is almost halfway through its 11-billion-year lifetime.

About 4.6 billion years ago, our solar system formed. The oldest fossils of a living organism date from about 3.5 billion years ago and represent cyanobacteria. Life evolved, and 65 million years ago, the dinosaurs and many other species were extinguished, probably from a catastrophic meteor impact. Modern humans evolved no earlier than a few hundred thousand years ago, a blink of an eye on the cosmic timescale.

Contributed By:
Jay M. Pasachoff.