High Temperature Superconductivity

Information about High Temperature Superconductivity

Unsolved problems in physics: What is the responsible mechanism that causes certain materials to exhibit superconductivity at temperatures much higher than around 50 kelvin?

High-temperature superconductors (abbreviated high $\text{[math]}$ ) are a family of superconducting materials containing copper-oxide planes as a common structural feature. For this reason, the term is often used interchangeably with cuprate superconductors.

This feature allows some materials to support superconductivity at temperatures above the boiling point of liquid nitrogen (77 K or -196Â°C). Indeed, they offer the highest transition temperatures of all superconductors. The ability to use relatively inexpensive and easily handled liquid nitrogen as a coolant has increased the range of practical applications of superconductivity.

Although cuprate compounds in the normal superconducting state share many characteristics with each other, there is as of 2007 no widely accepted theory to explain their properties. The search for a unified theory of high-temperature superconductivity is a topic of active experimental and theoretical research. Cuprate superconductors differ in many important ways from conventional superconductors, such as elemental mercury or lead, which are adequately explained by the BCS theory.

High- $\text{[math]}$ superconductivity was discovered in 1986; until then it was thought that BCS theory ruled out superconductivity at temperatures above 30 K. The experimental discovery of the first high- $\text{[math]}$ superconductor by Karl MÃ¼ller and Johannes Bednorz was immediately recognized by the Nobel Prize in Physics in 1987.

Relevant structural features

Copper-oxide planes

The cuprates are quasi-two-dimensional materials which consist of layers of copper-oxide planes separated by other materials. It seems that most of the properties are determined by electrons moving within the copper-oxide planes. The remaining components play structural roles and provide screening and doping environments. The copper-oxide plane is a checkerboard lattice with square backbone lattice of oxygens in the O^-- state and with, say, "black" squares marked by copper atom in the center; Copper is typically in Cu⁺⁺ state. The unit cell is, e.g., a square rotated by 45Â° containing exactly one "black square". The unit cell contains one copper and two oxygen atoms. Obviously, the unit cell is charged by an equivalent of two electronic charges. These charges are "supplied" by the La, Ba, Sr or other atoms which in cuprate superconductors are always present between the planes. It may be considered as an experimental fact that the chemical potential crosses one of the electronic bands of the copper-oxide plane and nothing else: it is the copper-oxide plane that determines the Fermi surface and low-energy electronic properties. As such, in the ionization state Cu⁺⁺O₂^--, the copper-oxide plane is a Mott insulator with long-range antiferromagnetic order of spins at small enough temperatures. A vital feature of cuprates is their ability to accommodate chemical substitutions, i.e., atoms that (i) replace one of the atoms of the original without disrupting the short-range lattice order and (ii) have a different number of electrons in their outer shells. The excess electrons may enter the copper oxide plane (electron doping) or electrons can be taken away from the copper-oxide plane (hole doping), as a result of such chemical substitution. It is important that chemical substitutions occur in the substance outside the copper-oxide plane. In other words, a unique property of copper-oxide planes and their "environment" atoms in the copper-oxide superconductors is that such doping is possible at all and charge redistribution is effectively screened and is stable. (Materials that allow doping are not very common, but cuprate superconductors are by no means the only ones). Structural formulas of interesting cuprate superconductors typically contain fractional numbers since they are constitute doping modifications of the particular "mother" compound. Concentration of excess electrons or holes (in short, doping) is one of the most important parameters that determine the low-energy properties of the cuprate compounds.

Weak distortions

Copper-oxide planes in real material are distorted in several ways. This distortions are usually weak but they can play an important role because they break the symmetries of the original (square, plane) lattice.

buckling
orthorhombic distortion
pairs of planes

General phase diagram

Typically the half-filling state is an insulator with antiferromagnetic ordering and it is not superconducting at any temperature. The "interesting" phases are in the metallic state which is achieved at finite electron/hole doping of copper-oxide planes. The common way of doping is by chemical substitution; other methods, such as pressure may also be used. The "geography" of the copper-oxide materials can in the doping-temperature diagram.

History and Progress

The term high-temperature superconductor was first used to designate the new family of cuprate-perovskite ceramic materials discovered by Johannes Georg Bednorz and Karl Alexander MÃ¼ller in 1986,^[1] for which they won the Nobel Prize in Physics the following year. Their discovery of the first high-temperature superconductor, La Ba CuO, with a transition temperature of 35 K, generated great excitement.

Recently, other unconventional superconductors, not based on cuprate structure, have been discovered. Some have unusually high values of the critical temperature, $\text{[math]}$ , and hence they are sometimes also called high-temperature superconductors. The record-high $\text{[math]}$ at standard pressure, 138 K, is held by a cuprate-perovskite material,^[2] although slightly higher transition temperatures have been achieved under pressure.^[3] Nevertheless, some researchers believe that if a room-temperature superconductor is ever discovered, it will be in a different family of materials.

Types of High-Temperature Superconductors

Examples of high- $\text{[math]}$ cuprate superconductors include La_1.85Ba_0.15CuO₄, and YBCO (Yttrium-Barium-Copper-Oxide), which is famous as the first material to achieve superconductivity above the boiling point of liquid nitrogen.

All known high- $\text{[math]}$ superconductors are Type-II superconductors. In contrast to Type-I superconductors, which expel all magnetic fields due to the Meissner Effect, Type-II superconductors allow magnetic fields to penetrate their interior in quantized units of flux, creating "holes" or "tubes" of normal metallic regions in the superconducting bulk. Consequently, high- $\text{[math]}$ superconductors can sustain much higher magnetic fields.

How High-Temperature Superconductors are Made

Perovskites are made by mixing oxides in stoichiometric quantities and then heating in a kiln at high temperatures in a concentrated oxygen atmosphere.

Ongoing Research

A small sample of the high-temperature superconductor BSCCO-2223. The two lines in the background are 1 mm apart.

The question of how superconductivity arises in high-temperature superconductors is one of the major unsolved problems of theoretical condensed matter physics as of 2007. The mechanism that causes the electrons in these crystals to form pairs is not known.

Despite intensive research and many promising leads, an explanation has so far eluded scientists. One reason for this is that the materials in question are generally very complex, multi-layered crystals (for example, BSCCO), making theoretical modeling difficult. However, with the rapid rate of new discoveries in the field, many researchers are optimistic that a complete understanding of the process is possible within the next decade or so.

References

1. ^ J. G. Bednorz and K. A. MÃ¼ller (1986). "Possible high $\text{[math]}$ superconductivity in the Ba−La−Cu−O system". Z. Physik, B 64: 189-193. DOI:10.1007/BF01303701.
2. ^ [1]
3. ^ L. Gao, Y. Y. Xue, F. Chen, Q. Xiong, R. L. Meng, D. Ramirez, C. W. Chu, J. H. Eggert, and H. K. Mao (1994). "Superconductivity up to 164 K in HgBa₂Ca_m-1Cu_mO_2m+2+δ (m=1, 2, and 3) under quasihydrostatic pressures". Phys. Rev. B 50: 4260-4263. DOI:10.1103/PhysRevB.50.4260.

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This is a list of some of the unsolved problems in physics. Some of these problems are theoretical, meaning that existing theories seem incapable of explaining some observed phenomenon or experimental result.
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Superconductivity is a phenomenon occurring in certain materials at extremely low temperatures, characterized by exactly zero electrical resistance and the exclusion of the interior magnetic field (the Meissner effect).
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trillion fold).]]

Temperature is a physical property of a system that underlies the common notions of hot and cold; something that is hotter generally has the greater temperature. Temperature is one of the principal parameters of thermodynamics.
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The kelvin (symbol: K) is a unit increment of temperature and is one of the seven SI base units. The Kelvin scale is a thermodynamic (absolute) temperature scale where absolute zero — the coldest possible temperature — is zero kelvins
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Copper oxide could refer to:

Copper(I) oxide (cuprous oxide, Cu₂O), a red powder.
Copper(II) oxide (cupric oxide, CuO), a black powder.

External links

National Pollutant Inventory - Copper and compounds fact sheet

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Liquid nitrogen (liquid density at the triple point is 0.807 g/mL) is the liquid produced industrially in large quantities by fractional distillation of liquid air and is often referred to by the abbreviation, LN₂. It is pure nitrogen, in a liquid state.
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Celsius is, or relates to, the Celsius temperature scale (previously known as the centigrade scale). The degree Celsius (symbol: Â°C) can refer to a specific temperature on the Celsius scale
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Some of the technological applications of superconductivity include the production of magnetometers based on SQUIDs, digital circuits (including those based on Josephson junctions and rapid single flux quantum technology), Magnetic Resonance Imaging (MRI) and Nuclear magnetic
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Conventional superconductors are materials that display superconductivity as described by BCS theory or its extensions.(c.f. Unconventional superconductor)

Critical temperatures of some simple metals:
Element T_c (K)
Al 1.20
Hg 4.15
Mo 0.
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2, 1
(mildly basic oxide)
Electronegativity 2.00 (scale Pauling)
Ionization energies 1st: 1007.1 kJ/mol
2nd: 1810 kJ/mol
3rd: 3300 kJ/mol
Atomic radius 150 pm
Atomic radius (calc.
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2
(Amphoteric oxide)
Electronegativity 2.33 (scale Pauling)
Ionization energies
(more) 1st: 715.6 kJmol⁻¹
2nd: 1450.5 kJmol⁻¹
3rd: 3081.
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BCS theory (named after its creators, Bardeen, Cooper, and Schrieffer) explains conventional superconductivity, the ability of certain metals at low temperatures to conduct electricity without electrical resistance.
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Karl Alexander MÃ¼ller (born April 20, 1927) is a Swiss physicist and Nobel laureate. He received the Nobel Prize in Physics in 1987 with Johannes Georg Bednorz for their work in superconductivity in ceramic materials.
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Johannes Georg Bednorz (May 16, 1950) is a German physicist who shared the 1987 Nobel Prize in Physics for work in high-temperature superconductivity. He was born in Neuenkirchen, North Rhine-Westphalia, Germany to Anton and Elisabeth Bednorz.
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Nobel Prize in Physics (Swedish: Nobelpriset i fysik) is awarded once a year by the Royal Swedish Academy of Sciences. It is one of the six Nobel Prizes. The first prize was awarded in 1901.
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CheckerBoard is a simple freeware GUI for Microsoft Windows, for playing checkers by Martin Fierz. It reads the Portable Draughts Notation standard for checkers games and is a GUI for checkers engines.
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crystal structure is a unique arrangement of atoms in a crystal. A crystal structure is composed of a motif, a set of atoms arranged in a particular way, and a lattice. Motifs are located upon the points of a lattice, which is an array of points repeating periodically in three
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Mott Insulators are a class of materials that are expected to conduct electricity under conventional band theories, but which in fact turn out to be insulators when measured.
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antiferromagnetism, the spins of electrons align in a regular pattern with neighboring spins pointing in opposite directions. This is a different manifestation of magnetism.
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Copper oxide could refer to:

Copper(I) oxide (cuprous oxide, Cu₂O), a red powder.
Copper(II) oxide (cupric oxide, CuO), a black powder.

External links

National Pollutant Inventory - Copper and compounds fact sheet

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Perovskite (calcium titanium oxide, CaTiO₃) is a relatively rare mineral on the Earth's crust. Perovskite crystallizes in the orthorhombic (pseudocubic) crystal system.
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ceramic is derived from the Greek word κεραμικός (keramikos). The term covers inorganic non-metallic materials which are formed by the action of heat.
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Lanthanum (IPA: /ˈlanθənəm/) is a chemical element in the periodic table that has the symbol La and atomic number 57.
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Barium (IPA: /ˈbɛːɹiəm/) is a chemical element. It has the symbol Ba, and atomic number 56. Barium is a soft silvery metallic alkaline earth metal.
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High Temperature Superconductivity

Information about High Temperature Superconductivity

Relevant structural features

Copper-oxide planes

Weak distortions

General phase diagram

History and Progress

Types of High-Temperature Superconductors

How High-Temperature Superconductors are Made

Ongoing Research

References

See also

External links

External links

External links