Math Is Fun Forum

Q: Why does the jellybean go to school?
A: Because he wants to become a smartie.
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Q: What do you get when you cross Ice, chocolate, a big strawberry, a giant pineapple, and cold milk?
A: The world's best Sundae!
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Q: How many grams of protein are there in that slice of chocolate pie?
A: 3.14159265...
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Q: What do you call people who like to drink hot chocolate all year long?
A: Cocoa-Nuts.
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Life is like a box of chocolates, It doesn't last too long for fat people.
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Madagascar

Gist

Madagascar, an island nation off Africa's southeastern coast in the Indian Ocean, is the world's fourth-largest island, renowned for its incredible biodiversity, with over 90% of its wildlife—including lemurs—found nowhere else on Earth. Known for baobabs and unique landscapes, its capital is Antananarivo, and it features a blend of Malagasy, African, and Asian cultural influences.

Madagascar is known for its extraordinary biodiversity, especially its unique wildlife like lemurs and chameleons, found nowhere else, alongside unique landscapes such as the Avenue of the Baobabs, tropical rainforests, and spiny deserts, making it a biodiversity hotspot and a top destination for nature lovers seeking adventure. Its rich culture blends Indonesian and African influences, while it's also famous for vanilla and pepper production. 

Summary

Details

Madagascar is an island country lying off the southeastern coast of Africa. Madagascar is the fourth largest island in the world, after Greenland, New Guinea, and Borneo.

Although located some 250 miles (400 km) from the African continent, Madagascar’s population is primarily related not to African peoples but rather to those of Indonesia, more than 3,000 miles (4,800 km) to the east. The Malagasy peoples, moreover, do not consider themselves to be Africans, but, because of the continuing bond with France that resulted from former colonial rule, the island developed political, economic, and cultural links with the French-speaking countries of western Africa. The animal life and vegetation of the island are equally anomalous, differing greatly from that of nearby Africa and being in many respects unique. Although the coastlands have been known to Europeans for more than 400 years and to Arabs for much longer, recent historical development has been more intense and concentrated in the central plateau, which contains the capital city of Antananarivo (formerly Tananarive).

Land

Madagascar is located in the southwestern Indian Ocean and is separated from the African coast by the 250-mile- (400-km-) wide Mozambique Channel.

Relief

Madagascar consists of three parallel longitudinal zones—the central plateau, the coastal strip in the east, and the zone of low plateaus and plains in the west.

Situated between 2,500 and 4,500 feet (800 and 1,400 metres) above sea level, the plateau has been uplifted and worn down several times and is tilted to the west. Three massifs are more than 8,500 feet (2,600 metres) high. The Tsaratanana region in the north is separated from the rest of the plateau by the Tsaratanana Massif, whose summit, Maromokotro, reaches 9,436 feet (2,876 metres) and is the highest point on the island. Ankaratra Massif in the centre is an enormous volcanic mass whose summit, Tsiafajavona, is 8,671 feet (2,643 metres) high. Ankaratra is a major watershed divide separating three main river basins. Farther south, Andringitra is a vast granite massif north of Tôlan̈aro (Faradofay); it rises to 8,720 feet (2,658 metres) at Boby Peak.

The plateau slopes with some regularity toward the extreme southern plain, but its boundaries to the east and west are more abrupt. To the east it descends in a sharp fault, by vertical steps of 1,000 to 2,000 feet (300 to 600 metres). This cliff, which is called the Great Cliff or the Cliff of Angavo, is often impassable and is itself bordered by the Betsimisaraka Escarpment, a second and lower cliff to the east, which overhangs the coastal plain. Behind the scarp face are the remains of ancient lakes, including one called Alaotra. To the south the two steep gradients meet and form the Mahafaly and the Androy plateaus, which overhang the sea in precipitous cliffs. Toward the west the descent is made in a series of steps. However, in places the central plateau is bordered by an impassable escarpment, such as the Cliff of Bongolava in the west-central part of the island. To the extreme north the plateau is bordered by the low belt of the Ambohitra Mountains, which include a series of volcanic craters.

The coastal strip has an average width of about 30 miles (50 km). It is a narrow alluvial plain that terminates in a low coastline bordered with lagoons linked together by the Pangalanes (Ampangalana) Canal, which is more than 370 miles (600 km) long. To the south of Farafangana the coast becomes rocky, and in the southeast there occur many little bays. To the northeast is the deep Bay of Antongil (Antongila).

The western zone is between 60 and 125 miles (100 and 200 km) wide. Its sedimentary layers slope toward the Mozambique Channel and produce a succession of hills. The inland (eastern) side of these steep hills dominates the hollows formed in the soft sediments of the interior, while the other side descends to the sea in rocky slopes. The coastline is straight, bordered by small dunes and fringed with mangroves. The currents in the Mozambique Channel have favoured the offshore deposit of alluvium and the growth of river deltas. On the northwestern coast there are a number of estuaries and bays. This coast is bordered by coral reefs and volcanic islands, such as Nosy Be (Nossi-Bé), which protects Ampasindava Bay.

Drainage

The steep eastern face of the plateau is drained by numerous short, torrential rivers, such as the Mandrare, the Mananara, the Faraony, the Ivondro, and the Maningory, which discharge either into the coastal lagoons or directly into the sea over waterfalls and rapids. The more gently sloping western side of the plateau is crossed by longer and larger rivers, including the Onilahy, the Mangoky, the Tsiribihina, and the Betsiboka, which bring huge deposits of fertile alluvium down into the vast plains and many-channeled estuaries; the river mouths, while not completely blocked by this sediment, are studded with numerous sandbanks.

There are many lakes of volcanic origin on the island, such as Lake Itasy. Alaotra is the last surviving lake of the eastern slope. Lake Tsimanampetsotsa, near the coast south of Toliara (formerly Tuléar), is a large body of saline water that has no outlet.

Soils

The central plateau and the eastern coast are mainly composed of gneiss, granite, quartz, and other crystalline rock formations. The gneiss decomposes into red murrum, laterite, and deeper and more fertile red earths, giving Madagascar its colloquial name the Great Red Island. Fertile alluvial soils in the valleys support intensive cultivation. There also are scattered volcanic intrusions that produce fertile but easily erodible soils. Lake Alaotra is a large sedimentary pocket in the central plateau containing some of the island’s most productive farmland. The western third of the island consists entirely of deposits of sedimentary rock, giving rise to soils of medium to low fertility.

Climate of Madagascar

The hot, wet season extends from November to April and the cooler, drier season from May to October. The climate is governed by the combined effects of the moisture-bearing southeast trade and northwest monsoon winds as they blow across the central plateau. The trade winds, which blow throughout the year, are strongest from May to October. The east coast is to the windward and has a high annual rate of precipitation, reaching nearly 150 inches (3,800 mm) at Maroantsetra on the Bay of Antongil. As the winds cross the plateau, they lose much of their humidity, causing only drizzle and mists on the plateau itself and leaving the west in a dry rain shadow. The southwest in particular is almost desert, with the dryness aggravated by a cold offshore current.

The monsoon, bringing rain to the northwest coast of Madagascar and the plateau, is most noticeable during the hot, humid season. The wind blows obliquely onto the west coast, which receives a moderate amount of precipitation annually; the southwest, which is protected, remains arid. Annual precipitation drops from about 80 inches (about 2,000 mm) on the northwestern island of Nosy Be to about 40 inches (1,000 mm) at Maintirano on the west coast to about 14 inches (360 mm) at Toliara in the southwest. The plateau receives moderate levels of precipitation, with about 50 inches (1,200 mm) falling annually at both Antananarivo and Fianarantsoa, which lies about 200 miles (320 km) farther south.

July is the coolest month, with mean monthly temperatures around the island ranging from the low 50s F (low 10s C) to the high 70s F (mid-20s C), and December is the hottest month, with temperatures between the low 60s and mid-80s F (mid 10s and high 20s C). Temperatures generally decrease with elevation, being highest on the northwest coast and lowest on the plateau.

Tropical cyclones are an important climatic feature. They form far out over the Indian Ocean, especially from December to March, and approach the eastern coast, bringing torrential rains and destructive floods.

Plant and animal life

Much of the island was once covered with evergreen and deciduous forest, but little now remains except on the eastern escarpment and in scattered pockets in the west. The plateau is particularly denuded and suffers seriously from erosion. The forest has been cut in order to clear rice fields, to obtain fuel and building materials, and to export valuable timber such as ebony, rosewood, and sandalwood. About seven-eighths of the island is covered with prairie grasses and bamboo or small thin trees. There also are screw pines, palms, and reeds on the coasts. In the arid south of the island grow thorn trees, giant cacti, dwarf baobab trees, pachypodium succulents, and other xerophytes (drought-resistant plants) that are peculiar to the island.

Because of the island’s isolation, many zoologically primitive primates have survived and evolved into unique forms. About 40 species of lemurs are indigenous to Madagascar. Several unique hedgehoglike insectivores, such as the tenrec, have evolved there, and there are also many kinds of chameleons of varying size. Birds are numerous and include guinea fowl, partridges, pigeons, herons, ibis, flamingos, egrets, cuckoos, Asian robins, and several kinds of birds of prey. There are about 800 species of butterflies, many moths, and a variety of spiders. The only large or dangerous animals are the crocodiles, which occupy the rivers. The snakes, including the do, which is 10 to 13 feet (3 to 4 metres) in length, are harmless.

Inland waters contain tilapia (an edible perchlike fish), rainbow trout, and black bass. Marine fish and crustaceans abound on the coasts and in the lagoons, estuaries, and even in some upland streams. They include groupers, giltheads, tuna, sharks, sardines, whitings, crayfish, crabs, shrimps, mussels, and oysters. The coelacanth, referred to as a living fossil and once thought extinct for millions of years, inhabits offshore waters.

Additional Information

Located off the east coast of Africa in the Southwest Indian Ocean, Madagascar is the world’s fourth largest island; at 146 million acres, it’s almost the size of Texas. Madagascar’s climate is tropical along the coast, temperate inland, and arid in the south. The island harbors lush rain forests, tropical dry forests, plateaus, and deserts. Its more than 3,000 miles of coastline and over 250 islands are home to some of the world’s largest coral reef systems, tidal marshes, seagrass beds, and most extensive mangrove areas in the Western Indian Ocean.

More than 11,000 endemic plant species, including seven species of baobab tree and all lemur species, share Madagascar with a vast variety of mammals, reptiles, fish, amphibians, and birds. Along the Northern Mozambique Channel, in the northwest, is Nosy Hara National Park, a world hotspot of marine diversity where an incredible 265 species of corals can be found. The country’s interior has several critically threatened species including the smallest chameleon in the world, Brookesia micra, and Verreaux’s sifaka, a lemur found in the southwest forests.

People and communities of Madagascar

Madagascar has a population of more than 21 million people with a wide array of faiths and customs, more than 20 ethnic groups coexist on the island. A majority of the population—70 percent of which is estimated to live below the international poverty line—depends completely on natural resources via subsistence farming and fishing. The ocean surrounding Madagascar has long been an important resource for coastal populations. 1.5 million people depend on fishing for their livelihoods and marine ecotourism is a growing sector of the national economy. Well over half of fishers are women and women are the primary cleaners, processors, and sellers of marine products.

Climate change

Climate change is causing increased and more severe drought in the south and more intense cyclones and flooding in the middle and north regions of Madagascar. This extreme weather forces millions of people to migrate across the country and puts added pressure on resources, including forests and fisheries. Warming oceans due to climate change is also leading to mass mortality in coral reefs.

Deforestation

The small-scale but widespread clearance of inland forest and coastal mangroves, primarily for firewood and charcoal production, is jeopardizing the island’s habitats and species such as lemurs and chameleons. Deforestation increases sediment flow out to the ocean and can smother coral reefs and reduce the productivity of fisheries.

Climate change has also increased the severity of droughts. Droughts are causing a surge in migration towards the country’s coastal areas and people are transitioning from agriculture to fishing, putting additional pressure on coastal environments and increasing demand for mangrove charcoal and timber. Over 12,000 acres of mangroves have been lost since 1996.

Governance and security

Only 3.1% of marine areas are formally protected in Madagascar and limited staff capacity and resources to manage and create marine protected areas hinder effective legislation. Management issues can impact distribution of industrial fisheries licenses and fish trader permits while inadequate monitoring, control, surveillance, and enforcement can exacerbate overfishing and illegal fishing.

The complicated history of Madagascar and its legal system contributes to significant policy variations across the country, complicating integration across economic sectors and with the broader Southwest Africa region to address cross-cutting policy and governance issues.

Unsustainable Fishing

It is estimated that some 130,000 tons of fish are illegally fished from Madagascar’s marine territories every year, amounting to a loss of $142.8 million in potential income. Bottom trawling and seine netting degrade and damage coral reefs, threatening the long-term resource availability and food security for coastal communities. As reefs degrade, fishers are forced to find different, less exploited reefs and may repeat the same damaging practices. Under weak governance and rising insecurity, unsustainable fishing practices thrive and threaten coastal livelihoods and food security. Illegal, unreported, and unregulated fishing is a pervasive problem and contributes to overfishing.

Borneo

Gist

Borneo is the world's third-largest island, covering approximately 748,168 square kilometers (288,869 sq miles). Located in Southeast Asia, it is the largest island in Asia and is divided among three countries: Indonesia (roughly 73%), Malaysia (around 26%), and Brunei (about 1%). Known for its immense biodiversity and ancient rainforests, it is also a major center for wildlife. 

Borneo is famous for its ancient, biodiverse rainforests, unique wildlife (orangutans, proboscis monkeys, pygmy elephants), world-class diving, and stunning landscapes, including Mount Kinabalu, making it a prime destination for eco-tourism, adventure, and experiencing rich indigenous cultures. It's known as a hotspot for endemic species and hosts the world's largest flower, Rafflesia arnoldii.

Summary

Borneo is the third-largest island in the world, with an area of 748,168 sq km (288,869 sq mi), and population of 23,053,723 (2020 national censuses). Situated at the geographic centre of Maritime Southeast Asia, it is one of the Greater Sunda Islands, located north of Java, west of Sulawesi, and east of Sumatra. The island is crossed by the equator, which divides it roughly in half. In Indonesia, the island is also known as Kalimantan, which is also the name of the Indonesian region located on the island.

The geology of Borneo was formed beginning in the Mesozoic. It formed part of Sundaland, a region connected to mainland Asia, until it became isolated by sea level rise at the end of the last ice age. With seven unique ecoregions, including large expanses of some of the oldest tropical rainforests in the world, Borneo is rich in biodiversity and endemic species.

Archaeological evidence suggests Borneo has been inhabited by humans for more than 65,000 years. Borneo is home to hundreds of different Indigenous groups, cultures and languages, loosely grouped under the term "Dayak". International trading ports were well established on Borneo by the first millennium. It was later subsumed into the Majapahit Empire. The Sultanate of Sulu later ruled much of the island's North, and at its peak in the 14th century, the Sultanate of Brunei governed most of its coast; meanwhile, Borneo's interior remained largely outside of their control. Borneo was later colonised by the British and Dutch, and occupied by Japan during World War II.

Since the decolonisation of Asia, the island has been politically divided among three states, with the borders broadly following previous demarcation between the British and Dutch. The sovereign state of Brunei in the north makes up 1% of the territory. Approximately 73% of Borneo is Indonesian territory, and in the north, the East Malaysian states of Sabah and Sarawak make up about 26% of the island. The Malaysian federal territory of Labuan is situated on a small island just off the coast of Borneo.

The majority of Borneo's inhabitants reside in coastal cities. It is the site of Indonesia's planned future capital, Nusantara. Major economic sectors include oil and gas, agriculture, timber and tourism. Industrial deforestation in Indonesian and Malaysian Borneo for timber and agricultural conversion has taken place during the past century.

Details

Borneo is an island in the extreme southwestern part of the Pacific Ocean. It is the third largest island in the world, surpassed in size by only Greenland and New Guinea.

Borneo is situated southeast of the Malay Peninsula in the Greater Sunda Islands group of the Malay Archipelago. The island is bounded by the South China Sea to the northwest, the Sulu Sea to the northeast, the Celebes Sea to the east, and the Java Sea to the south—the latter separating Borneo from the island of Java. The Makassar Strait separates Borneo from the island of Celebes (Sulawesi) to the east and southeast, and a series of shallow seas and straits lie between Borneo and the island of Sumatra to the west.

Indonesia constitutes the largest political component of the island (in Indonesian known as Kalimantan), its territory divided into five provinces: Central Kalimantan, East Kalimantan, North Kalimantan, South Kalimantan, and West Kalimantan. Along the northwest coast and northern tip lie Sarawak and Sabah, two constituent states of Malaysia that are often collectively called East Malaysia, and between them is the Islamic sultanate of Brunei. Area (including adjacent islands), about 292,000 square miles (755,000 square km). Pop. (2015) five provinces of Kalimantan (including adjacent islands), 15,320,017; (2010) Sabah and Sarawak, 5,677,882; (2014 est.) Brunei, 411,900.

Land

Borneo lies astride the Equator. It has a length of 830 miles (1,336 km) from northeast to southwest and a maximum breadth of 600 miles (960 km). The island is largely mountainous, although there are extensive lowlands, especially in Central Kalimantan and Sarawak, that are often swampy along the coasts. A long series of mountain ranges extend southwest across the island from Mount Kinabalu in the far northeast, which, at an elevation of 13,455 feet (4,101 metres), is the island’s greatest height and is also the tallest peak in Malaysia. Ranges in the central spine include the Crocker, the Nieuwenhuis, and the Muller mountains. The Kapuas Hulu Mountains branch westward from the central core along the border between Sarawak and West Kalimantan, and a separate and discontinuous series of ranges parallel the east and southeast coasts in East and South Kalimantan.

A large part of Borneo is drained by navigable rivers, which represent the principal and often the only lifelines of trade and commerce. The main rivers of Kalimantan are the Kapuas in the west and the Mahakam in the east. Farther north, as the island narrows, few rivers are navigable for more than 100 miles (160 km), often much less, a condition largely responsible for the northern interior of Borneo remaining, until recently, one of the least-known parts of the world. The main river of East Malaysia is the Rajang in Sarawak.

Borneo’s climate is equatorial—hot and humid with a fairly distinct division into two seasons, consisting of a wet monsoonal period (landas) between October and March and a relatively drier, calmer period of summer (tedoh) for the rest of the year. The average annual rainfall is about 150 inches (3,800 mm).

Borneo is largely covered in dense rainforest, and both the floral and the faunal populations of the island are extremely varied. There are extensive stands of teak, oak, conifers, and hardwoods of the Dipterocarpaceae family (including members the commercially valuable genus Shorea). The forests are also noted for their epiphytes and for the monster flower (Rafflesia arnoldii), the largest flower in the world. Mammals endemic to the island include the Bornean clouded leopard (Neofelis diardi) and the proboscis monkey (Nasalis larvatus). Other notable animals include orangutans, gibbons, and elephants, but the Sumatran rhinoceros is now extinct there. There are also a great many species of birds, insects, and fish.

People and economy

The island is sparsely inhabited by Asian standards. The population, of which more than two-thirds is in Indonesian territory, is varied. It includes non-Muslim Dayaks, Islamic Malays, Chinese, and a small minority of Europeans. The highest population densities are in South Kalimantan and in eastern, western, and northern coastal areas.

Borneo is poor in commercial mineral resources. Gold, diamonds, antimony, mercury, gypsum, and iron have all at some time since the beginning of the 19th century been exploited on an individual producer basis, using small-scale methods. There are oil fields at Tanjung Balikpapan, in Brunei, and at more than a dozen other sites on the continental shelf off the north shore of the island. East coast development is centred on the Attaka area. Bauxite has been developed near Cape Datu in the southwest since the late 1950s, and coal has been mined in the southwest.

Generally, Borneo soils are poor, with a few exceptions of fertile volcanic areas. Rice, the staple food, is supplemented with corn (maize), cassava (manioc), cucumber, and pumpkin. Rubber is grown on small native plantations. Pepper is grown on a large scale by the resident Chinese. Newer markets are for the seeds of the shorea tree and for chicle. Coastal area exports are sago, copra, cutch (a dye extracted from mangrove bark), and marine products. Tobacco is grown in the uplands and traded to the lowlands. Experimental plantings of coffee, cocoa, and hemp have been made.

History of Borneo

Evidence for prehistoric human occupation of Borneo has been found at Neah Cave in Sarawak, including fossil bones, stone tools, and wall and ceiling paintings. Borneo is first mentioned in Ptolemy’s Guide to Geography of about 150 ce. Roman trade beads and Indo-Javanese artifacts have been discovered that give evidence of a flourishing civilization dating to the 2nd or 3rd century ce. Three rough foundation stones with an inscription recording a gift to a Brahman priest dated from the early 5th century, found at Kutai, provide evidence of a Hindu kingdom in eastern Kalimantan. Brahmanic and Buddhist images in the Gupta style have been found in the valleys of the Kapuas and other rivers in western Kalimantan. Later Kalimantan rulers were probably feudatories of the Majapahit empire of eastern Java (c. 1293–1520). With the arrival of Islam early in the 16th century, a number of Muslim kingdoms were founded, including the Banjarmasin, Sambas, Sukadana, and Landak. The Sukadana rulers owed allegiance to the Muslim Mataram kingdom of Java.

Modern European knowledge of Borneo dates from travelers who passed through Southeast Asia in the 14th century. The first recorded European visitor was the Franciscan friar Odoric of Pordenone, who visited Talamasim on his way from India to China in 1330. The Portuguese, followed by the Spanish, established trading relations on the island early in the 16th century. At the beginning of the 17th century the Portuguese and Spanish trade monopoly was broken by the Dutch, who, intervening in the affairs of the Muslim kingdoms, succeeded in replacing Mataram influence with their own. The coastal strip along the South China and Sulu seas was long oriented toward the Philippines to the northeast and was often raided by Sulu pirates. British interests, particularly in the north and west, diminished that of the Dutch. The Brunei sultanate was an Islamic kingdom that at one time had controlled the whole island but by the 19th century ruled only in the north and northwest. In 1841 Sarawak was split away on the southwest, becoming an independent kingdom ruled by the Brooke Raj. North Borneo (later Sabah) to the northeast was obtained by a British company to promote trade and suppress piracy, but it was not demarcated until 1912. Those losses left a much-reduced Brunei, which became a British protectorate in 1888.

During World War II the Japanese invasions of Borneo (1941–42) quickly eliminated the token British and Dutch forces on the island, which was not retaken until 1945. In July 1946 both Sarawak and North Borneo were made British crown colonies. In Dutch Borneo a strong nationalist sentiment developed and led to fighting between Indonesian and Dutch forces as the latter attempted to reimpose Netherlands control. Sovereignty passed to the Indonesians in 1949, and in 1950 a new constitution proclaimed Dutch Borneo part of the Republic of Indonesia.

The British government relinquished its sovereignty over Sabah and Sarawak in 1963, when those territories joined the Malaysian federation. That marked the commencement of Indonesian hostilities in the form of guerrilla raids across the border. Those raids ceased by agreement in 1966. Except for the period of Japanese occupation, Brunei remained a British protectorate until 1983. It became fully independent on January 1, 1984.

Additional Information

Borneo is the world's third-largest island and the largest island of Asia. It is part of the Indonesian archipelago. Borneo is surrounded by the Java Sea to its south, the Celebes Sea on its east, and the South China Sea to its north. It has an area of 288,869 square miles (748,168 square kilometers).

From neighboring islands, Borneo is north of Java, west of Sulawesi, and east of Sumatra. The island is bisected by the equator, with approximately half of its land area in the northern hemisphere and half in the southern hemisphere.

The island is divided between three countries: Indonesia (73%), Malaysia (26%), and Brunei (1%). The Indonesian provinces of North Kalimantan, South Kalimantan, East Kalimantan, West Kalimantan, and Central Kalimantan make up the southeastern part of the island. The Malaysian states of Sabah and Sarawak make up the northwestern part of the island. Brunei is a sovereign state located almost entirely on Borneo. It consists of two coastal tracts within the Malaysian state of Sarawak, and also includes several small adjacent islands.

The island of Borneo is rich in natural resources. Known metal deposits include: gold, silver, copper, tin, aluminum (as bauxite), and iron ore. Most of the island is covered by tropical forests that produce tropical timber and other forest products. The coastal and offshore areas are underlain by deposits of coal, peat, oil, and natural gas.

Superconductivity

Gist

Superconductivity is a quantum mechanical phenomenon occurring in certain materials cooled below a specific critical temperature, characterized by exactly zero electrical resistance and the expulsion of magnetic fields (Meissner effect). It allows for lossless energy transmission and magnetic levitation. Key applications include MRI machines, particle accelerators, and maglev trains. 

Superconductivity is when a material, cooled to very low temperatures, lets electricity flow through it with zero resistance, meaning no energy is lost as heat, and it also perfectly pushes away magnetic fields. Think of it like a perfect, frictionless highway for electrons, allowing current to flow forever without a power source once started, and even levitating magnets above it.

Summary

Superconductivity is a set of physical properties observed in superconductors: materials where electrical resistance vanishes and magnetic fields are expelled from the material. Unlike an ordinary metallic conductor, whose resistance decreases gradually as its temperature is lowered, even down to near absolute zero, a superconductor has a characteristic critical temperature below which the resistance drops abruptly to zero. An electric current through a loop of superconducting wire can persist indefinitely with no power source.

The superconductivity phenomenon was discovered in 1911 by Dutch physicist Heike Kamerlingh Onnes. Like ferromagnetism and atomic spectral lines, superconductivity is a phenomenon which can only be explained by quantum mechanics. It is characterized by the Meissner effect, the complete cancellation of the magnetic field in the interior of the superconductor during its transitions into the superconducting state. The occurrence of the Meissner effect indicates that superconductivity cannot be understood simply as the idealization of perfect conductivity in classical physics.

In 1986, it was discovered that some cuprate-perovskite ceramic materials have a critical temperature above 35 K (−238 °C). It was shortly found (by Ching-Wu Chu) that replacing the lanthanum with yttrium, i.e. making YBCO, raised the critical temperature to 92 K (−181 °C), which was important because liquid nitrogen could then be used as a refrigerant. Such a high transition temperature is theoretically impossible for a conventional superconductor, leading the materials to be termed high-temperature superconductors. The cheaply available coolant liquid nitrogen boils at 77 K (−196 °C) and thus the existence of superconductivity at higher temperatures than this facilitates many experiments and applications that are less practical at lower temperatures.

Details

superconductivity, complete disappearance of electrical resistance in various solids when they are cooled below a characteristic temperature. This temperature, called the transition temperature, varies for different materials but generally is below 20 K (−253 °C).

The use of superconductors in magnets is limited by the fact that strong magnetic fields above a certain critical value, depending upon the material, cause a superconductor to revert to its normal, or nonsuperconducting, state, even though the material is kept well below the transition temperature.

Suggested uses for superconducting materials include medical magnetic-imaging devices, magnetic energy-storage systems, motors, generators, transformers, computer parts, and very sensitive devices for measuring magnetic fields, voltages, or currents. The main advantages of devices made from superconductors are low power dissipation, high-speed operation, and high sensitivity.

Discovery

Superconductivity was discovered in 1911 by the Dutch physicist Heike Kamerlingh Onnes; he was awarded the Nobel Prize for Physics in 1913 for his low-temperature research. Kamerlingh Onnes found that the electrical resistivity of a mercury wire disappears suddenly when it is cooled below a temperature of about 4 K (−269 °C); absolute zero is 0 K, the temperature at which all matter loses its disorder. He soon discovered that a superconducting material can be returned to the normal (i.e., nonsuperconducting) state either by passing a sufficiently large current through it or by applying a sufficiently strong magnetic field to it.

For many years it was believed that, except for the fact that they had no electrical resistance (i.e., that they had infinite electrical conductivity), superconductors had the same properties as normal materials. This belief was shattered in 1933 by the discovery that a superconductor is highly diamagnetic; that is, it is strongly repelled by and tends to expel a magnetic field. This phenomenon, which is very strong in superconductors, is called the Meissner effect for one of the two men who discovered it. Its discovery made it possible to formulate, in 1934, a theory of the electromagnetic properties of superconductors that predicted the existence of an electromagnetic penetration depth, which was first confirmed experimentally in 1939. In 1950 it was clearly shown for the first time that a theory of superconductivity must take into account the fact that free electrons in a crystal are influenced by the vibrations of atoms that define the crystal structure, called the lattice vibrations. In 1953, in an analysis of the thermal conductivity of superconductors, it was recognized that the distribution of energies of the free electrons in a superconductor is not uniform but has a separation called the energy gap.

The theories referred to thus far served to show some of the interrelationships between observed phenomena but did not explain them as consequences of the fundamental laws of physics. For almost 50 years after Kamerlingh Onnes’s discovery, theorists were unable to develop a fundamental theory of superconductivity. Finally, in 1957 such a theory was presented by the physicists John Bardeen, Leon N. Cooper, and John Robert Schrieffer of the United States; it won for them the Nobel Prize for Physics in 1972. It is now called the BCS theory in their honour, and most later theoretical work is based on it. The BCS theory also provided a foundation for an earlier model that had been introduced by the Russian physicists Lev Davidovich Landau and Vitaly Lazarevich Ginzburg (1950). This model has been useful in understanding electromagnetic properties, including the fact that any internal magnetic flux in superconductors exists only in discrete amounts (instead of in a continuous spectrum of values), an effect called the quantization of magnetic flux. This flux quantization, which had been predicted from quantum mechanical principles, was first observed experimentally in 1961.

In 1962 the British physicist Brian D. Josephson predicted that two superconducting objects placed in electric contact would display certain remarkable electromagnetic properties. These properties have since been observed in a wide variety of experiments, demonstrating quantum mechanical effects on a macroscopic scale.

The theory of superconductivity has been tested in a wide range of experiments, involving, for example, ultrasonic absorption studies, nuclear-spin phenomena, low-frequency infrared absorption, and electron-tunneling experiments. The results of these measurements have brought understanding to many of the detailed properties of various superconductors.

Additional Information

At what most people think of as “normal” temperatures, all materials have some amount of electrical resistance. This means they resist the flow of electricity in the same way a narrow pipe resists the flow of water. Because of resistance, some energy is lost as heat when electrons move through the electronics in our devices, like computers or cell phones. For most materials, this resistance remains even if the material is cooled to very low temperatures. The exceptions are superconducting materials. Superconductivity is the property of certain materials to conduct direct current (DC) electricity without energy loss when they are cooled below a critical temperature (referred to as Tc). These materials also expel magnetic fields as they transition to the superconducting state.

Superconductivity is one of nature’s most intriguing quantum phenomena. It was discovered more than 100 years ago in mercury cooled to the temperature of liquid helium (about -452°F, only a few degrees above absolute zero). Early on, scientists could explain what occurred in superconductivity, but the why and how of superconductivity were a mystery for nearly 50 years.

In 1957, three physicists at the University of Illinois used quantum mechanics to explain the microscopic mechanism of superconductivity. They proposed a radically new theory of how negatively charged electrons, which normally repel each other, form into pairs below Tc. These paired electrons are held together by atomic-level vibrations known as phonons, and collectively the pairs can move through the material without resistance. For their discovery, these scientists received the Nobel Prize in Physics in 1972.

Following the discovery of superconductivity in mercury, the phenomenon was also observed in other materials at very low temperatures. The materials included several metals and an alloy of niobium and titanium that could easily be made into wire. Wires led to a new challenge for superconductor research. The lack of electrical resistance in superconducting wires means that they can support very high electrical currents, but above a “critical current” the electron pairs break up and superconductivity is destroyed. Technologically, wires opened whole new uses for superconductors, including wound coils to create powerful magnets. In the 1970s, scientists used superconducting magnets to generate the high magnetic fields needed for the development of magnetic resonance imaging (MRI) machines. More recently, scientists introduced superconducting magnets to guide electron beams in synchrotrons and accelerators at scientific user facilities.

In 1986, scientists discovered a new class of copper-oxide materials that exhibited superconductivity, but at much higher temperatures than the metals and metal alloys from earlier in the century. These materials are known as high-temperature superconductors. While they still must be cooled, they are superconducting at much warmer temperatures—some of them at temperatures above liquid nitrogen (-321°F). This discovery held the promise of revolutionary new technologies. It also suggested that scientists may be able to find materials that are superconducting at relatively high temperatures.

Since then, many new high-temperature superconducting materials have been discovered using educated guesses combined with trial-and-error experiments, including a class of iron-based materials. However, it also became clear that the microscopic theory that describes superconductivity in metals and metal alloys does not apply to most of these new materials, so once again the mystery of superconductivity is challenging the scientific community.

DOE Office of Science & Superconductivity

The DOE Office of Science, Office of Basic Energy Sciences has supported research on high-temperature superconducting materials since they were discovered. The research includes theoretical and experimental studies to unravel the mystery of superconductivity and discover new materials. Even though a complete understanding of the quantum mechanism is yet to be discovered, scientists have found ways to enhance superconductivity (increase the critical temperature and critical current) and have discovered many new families of high-temperature superconducting materials. Each new superconducting material offers scientists an opportunity to get closer to understanding how high-temperature superconductivity works and how to design new superconducting materials for advanced technological applications.

Superconductivity Facts

* Superconductivity was discovered in 1911 by Heike Kamerlingh-Onnes. For this discovery, the liquefaction of helium, and other achievements, he won the 1913 Nobel Prize in Physics.
* Five Nobel Prizes in Physics have been awarded for research in superconductivity (1913, 1972, 1973, 1987, and 2003).
* Approximately half of the elements in the periodic table display low temperature superconductivity, but applications of superconductivity often employ easier to use or less expensive alloys. For example, MRI machines use an alloy of niobium and titanium.

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