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Quasicrystal

April 26, 2024

Not to be confused with Quasi-crystals (supramolecular).

A quasiperiodic crystal, or quasicrystal, is a structure that is ordered but not periodic. A quasicrystalline pattern can continuously fill all available space, but it lacks translational symmetry.[2] While crystals, according to the classical crystallographic restriction theorem, can possess only two-, three-, four-, and six-fold rotational symmetries, the Bragg diffraction pattern of quasicrystals shows sharp peaks with other symmetry orders—for instance, five-fold.[3]

Potential energy surface for silver depositing on an aluminiumpalladiummanganese (Al–Pd–Mn) quasicrystal surface. Similar to Fig. 6 in Ref.[1]

Aperiodic tilings were discovered by mathematicians in the early 1960s, and, some twenty years later, they were found to apply to the study of natural quasicrystals. The discovery of these aperiodic forms in nature has produced a paradigm shift in the field of crystallography. In crystallography the quasicrystals were predicted in 1981 by a five-fold symmetry study of Alan Lindsay Mackay,[4]—that also brought in 1982, with the crystallographic Fourier transform of a Penrose tiling,[5] the possibility of identifying quasiperiodic order in a material through diffraction.

Quasicrystals had been investigated and observed earlier,[6] but, until the 1980s, they were disregarded in favor of the prevailing views about the atomic structure of matter. In 2009, after a dedicated search, a mineralogical finding, icosahedrite, offered evidence for the existence of natural quasicrystals.[7]

Roughly, an ordering is non-periodic if it lacks translational symmetry, which means that a shifted copy will never match exactly with its original. The more precise mathematical definition is that there is never translational symmetry in more than n – 1 linearly independent directions, where n is the dimension of the space filled, e.g., the three-dimensional tiling displayed in a quasicrystal may have translational symmetry in two directions. Symmetrical diffraction patterns result from the existence of an indefinitely large number of elements with a regular spacing, a property loosely described as long-range order. Experimentally, the aperiodicity is revealed in the unusual symmetry of the diffraction pattern, that is, symmetry of orders other than two, three, four, or six. In 1982, materials scientist Dan Shechtman observed that certain aluminiummanganese alloys produced the unusual diffractograms which today are seen as revelatory of quasicrystal structures. Due to fear of the scientific community's reaction, it took him two years to publish the results[8][9] for which he was awarded the Nobel Prize in Chemistry in 2011.[10] On 25 October 2018, Luca Bindi and Paul Steinhardt were awarded the Aspen Institute 2018 Prize for collaboration and scientific research between Italy and the United States, after they discovered icosahedrite, the first quasicrystal known to occur naturally.

History edit

 
Girih-tile subdivision found in the decagonal girih pattern on a spandrel from the Darb-i Imam shrine, Isfahan, Iran (1453 C.E.). A subdivision rule to construct perfect quasi-crystalline tilings has been identified[11]

The first representations of perfect quasicrystalline patterns can be found in several early Islamic works of art and architecture such as the Gunbad-i-Kabud tomb tower, the Darb-e Imam shrine and the Al-Attarine Madrasa.[12][13] On July 16, 1945, in Alamogordo, New Mexico, the Trinity nuclear bomb test produced icosahedral quasicrystals. They went unnoticed at the time of the test but were later identified in samples of red Trinitite, a glass-like substance formed from fused sand and copper transmission lines. Identified in 2021, they are the oldest known anthropogenic quasicrystals.[14][15]

 
A Penrose tiling

In 1961, Hao Wang asked whether determining if a set of tiles admits a tiling of the plane is an algorithmically unsolvable problem or not. He conjectured that it is solvable, relying on the hypothesis that every set of tiles that can tile the plane can do it periodically (hence, it would suffice to try to tile bigger and bigger patterns until obtaining one that tiles periodically). Nevertheless, two years later, his student Robert Berger constructed a set of some 20,000 square tiles (now called "Wang tiles") that can tile the plane but not in a periodic fashion. As further aperiodic sets of tiles were discovered, sets with fewer and fewer shapes were found. In 1974 Roger Penrose discovered a set of just two tiles, now referred to as Penrose tiles, that produced only non-periodic tilings of the plane. These tilings displayed instances of fivefold symmetry. One year later Alan Mackay showed theoretically that the diffraction pattern from the Penrose tiling had a two-dimensional Fourier transform consisting of sharp 'delta' peaks arranged in a fivefold symmetric pattern.[16] Around the same time, Robert Ammann created a set of aperiodic tiles that produced eightfold symmetry.

In 1972, de Wolf and van Aalst[17] reported that the diffraction pattern produced by a crystal of sodium carbonate cannot be labeled with three indices but needed one more, which implied that the underlying structure had four dimensions in reciprocal space. Other puzzling cases have been reported,[18] but until the concept of quasicrystal came to be established, they were explained away or denied.[19][20]

Shechtman first observed ten-fold electron diffraction patterns in 1982, while conducting a routine study of an aluminiummanganese alloy, Al6Mn, at the US National Bureau of Standards (later NIST).[21] Shechtman related his observation to Ilan Blech, who responded that such diffractions had been seen before.[22][23][24] Around that time, Shechtman also related his finding to John W. Cahn of the NIST, who did not offer any explanation and challenged him to solve the observation. Shechtman quoted Cahn as saying: "Danny, this material is telling us something, and I challenge you to find out what it is".[25]

The observation of the ten-fold diffraction pattern lay unexplained for two years until the spring of 1984, when Blech asked Shechtman to show him his results again. A quick study of Shechtman's results showed that the common explanation for a ten-fold symmetrical diffraction pattern, a type of crystal twinning, was ruled out by his experiments. Therefore, Blech looked for a new structure containing cells connected to each other by defined angles and distances but without translational periodicity. He decided to use a computer simulation to calculate the diffraction intensity from a cluster of such a material, which he termed as "multiple polyhedral", and found a ten-fold structure similar to what was observed. The multiple polyhedral structure was termed later by many researchers as icosahedral glass.[26]

Shechtman accepted Blech's discovery of a new type of material and chose to publish his observation in a paper entitled "The Microstructure of Rapidly Solidified Al6Mn", which was written around June 1984 and published in a 1985 edition of Metallurgical Transactions A.[27] Meanwhile, on seeing the draft of the paper, John Cahn suggested that Shechtman's experimental results merit a fast publication in a more appropriate scientific journal. Shechtman agreed and, in hindsight, called this fast publication "a winning move”. This paper, published in the Physical Review Letters,[9] repeated Shechtman's observation and used the same illustrations as the original paper.

Originally, the new form of matter was dubbed "Shechtmanite".[28] The term "quasicrystal" was first used in print by Steinhardt and Levine[2] shortly after Shechtman's paper was published.

Also in 1985, Ishimasa et al. reported twelvefold symmetry in Ni-Cr particles.[29] Soon, eightfold diffraction patterns were recorded in V-Ni-Si and Cr-Ni-Si alloys.[30] Over the years, hundreds of quasicrystals with various compositions and different symmetries have been discovered. The first quasicrystalline materials were thermodynamically unstable—when heated, they formed regular crystals. However, in 1987, the first of many stable quasicrystals were discovered, making it possible to produce large samples for study and applications.[31]

In 1992, the International Union of Crystallography altered its definition of a crystal, reducing it to the ability to produce a clear-cut diffraction pattern and acknowledging the possibility of the ordering to be either periodic or aperiodic.[8][32]

 
Atomic image of a micron-sized grain of the natural Al71Ni24Fe5 quasicrystal (shown in the inset) from a Khatyrka meteorite fragment. The corresponding diffraction patterns reveal a ten-fold symmetry.[33]
 
Electron diffraction pattern of an icosahedral Ho–Mg–Zn quasicrystal

In 2001, Paul Steinhardt of Princeton University hypothesized that quasicrystals could exist in nature and developed a method of recognition, inviting all the mineralogical collections of the world to identify any badly cataloged crystals. In 2007 Steinhardt received a reply by Luca Bindi, who found a quasicrystalline specimen from Khatyrka in the University of Florence Mineralogical Collection. The crystal samples were sent to Princeton University for other tests, and in late 2009, Steinhardt confirmed its quasicrystalline character. This quasicrystal, with a composition of Al63Cu24Fe13, was named icosahedrite and it was approved by the International Mineralogical Association in 2010. Analysis indicates it may be meteoritic in origin, possibly delivered from a carbonaceous chondrite asteroid. In 2011, Bindi, Steinhardt, and a team of specialists found more icosahedrite samples from Khatyrka.[34] A further study of Khatyrka meteorites revealed micron-sized grains of another natural quasicrystal, which has a ten-fold symmetry and a chemical formula of Al71Ni24Fe5. This quasicrystal is stable in a narrow temperature range, from 1120 to 1200 K at ambient pressure, which suggests that natural quasicrystals are formed by rapid quenching of a meteorite heated during an impact-induced shock.[33]

Shechtman was awarded the Nobel Prize in Chemistry in 2011 for his work on quasicrystals. "His discovery of quasicrystals revealed a new principle for packing of atoms and molecules," stated the Nobel Committee and pointed that "this led to a paradigm shift within chemistry."[8][35] In 2014, Post of Israel issued a stamp dedicated to quasicrystals and the 2011 Nobel Prize.[36]

While the first quasicrystals discovered were made out of intermetallic components, later on quasicrystals were also discovered in soft-matter and molecular systems. Soft quasicrystal structures have been found in supramolecular dendrimer liquids[37] and ABC Star Polymers[38] in 2004 and 2007. In 2009, it was found that thin-film quasicrystals can be formed by self-assembly of uniformly shaped, nano-sized molecular units at an air-liquid interface.[39] It was demonstrated that these units can be both inorganic and organic.[40] Additionally in the 2010s, two-dimensional molecular quasicrystals were discovered, driven by intermolecular interactions[41] and interface-interactions.[42]

In 2018, chemists from Brown University announced the successful creation of a self-constructing lattice structure based on a strangely shaped quantum dot. While single-component quasicrystal lattices have been previously predicted mathematically and in computer simulations,[43] they had not been demonstrated prior to this.[44]

Mathematics edit

 
A 5-cube as an orthographic projection into 2D using Petrie polygon basis vectors overlaid on the diffractogram from an icosahedral Ho–Mg–Zn quasicrystal
 
A 6-cube projected into the rhombic triacontahedron using the golden ratio in the basis vectors. This is used to understand the aperiodic icosahedral structure of quasicrystals.

There are several ways to mathematically define quasicrystalline patterns. One definition, the "cut and project" construction, is based on the work of Harald Bohr (mathematician brother of Niels Bohr). The concept of an almost periodic function (also called a quasiperiodic function) was studied by Bohr, including work of Bohl and Escanglon.[45] He introduced the notion of a superspace. Bohr showed that quasiperiodic functions arise as restrictions of high-dimensional periodic functions to an irrational slice (an intersection with one or more hyperplanes), and discussed their Fourier point spectrum. These functions are not exactly periodic, but they are arbitrarily close in some sense, as well as being a projection of an exactly periodic function.

In order that the quasicrystal itself be aperiodic, this slice must avoid any lattice plane of the higher-dimensional lattice. De Bruijn showed that Penrose tilings can be viewed as two-dimensional slices of five-dimensional hypercubic structures;[46] similarly, icosahedral quasicrystals in three dimensions are projected from a six-dimensional hypercubic lattice, as first described by Peter Kramer and Roberto Neri in 1984.[47] Equivalently, the Fourier transform of such a quasicrystal is nonzero only at a dense set of points spanned by integer multiples of a finite set of basis vectors, which are the projections of the primitive reciprocal lattice vectors of the higher-dimensional lattice.[48]

Classical theory of crystals reduces crystals to point lattices where each point is the center of mass of one of the identical units of the crystal. The structure of crystals can be analyzed by defining an associated group. Quasicrystals, on the other hand, are composed of more than one type of unit, so, instead of lattices, quasilattices must be used. Instead of groups, groupoids, the mathematical generalization of groups in category theory, is the appropriate tool for studying quasicrystals.[49]

Using mathematics for construction and analysis of quasicrystal structures is a difficult task for most experimentalists. Computer modeling, based on the existing theories of quasicrystals, however, greatly facilitated this task. Advanced programs have been developed[50] allowing one to construct, visualize and analyze quasicrystal structures and their diffraction patterns. The aperiodic nature of quasicrystals can also make theoretical studies of physical properties, such as electronic structure, difficult due to the inapplicability of Bloch's theorem. However, spectra of quasicrystals can still be computed with error control.[51]

Study of quasicrystals may shed light on the most basic notions related to the quantum critical point observed in heavy fermion metals. Experimental measurements on an Au–Al–Yb quasicrystal have revealed a quantum critical point defining the divergence of the magnetic susceptibility as temperature tends to zero.[52] It is suggested that the electronic system of some quasicrystals is located at a quantum critical point without tuning, while quasicrystals exhibit the typical scaling behaviour of their thermodynamic properties and belong to the well-known family of heavy fermion metals.

Materials science edit

 
Tiling of a plane by regular pentagons is impossible but can be realized on a sphere in the form of pentagonal dodecahedron.
 
A Ho–Mg–Zn dodecahedral quasicrystal formed as a pentagonal dodecahedron, the dual of the icosahedron. Unlike the similar pyritohedron shape of some cubic-system crystals such as pyrite, the quasicrystal has faces that are true regular pentagons
 
TiMn quasicrystal approximant lattice

Since the original discovery by Dan Shechtman, hundreds of quasicrystals have been reported and confirmed. Quasicrystals are found most often in aluminium alloys (Al–Li–Cu, Al–Mn–Si, Al–Ni–Co, Al–Pd–Mn, Al–Cu–Fe, Al–Cu–V, etc.), but numerous other compositions are also known (Cd–Yb, Ti–Zr–Ni, Zn–Mg–Ho, Zn–Mg–Sc, In–Ag–Yb, Pd–U–Si, etc.).[53]

Two types of quasicrystals are known.[50] The first type, polygonal (dihedral) quasicrystals, have an axis of 8-, 10-, or 12-fold local symmetry (octagonal, decagonal, or dodecagonal quasicrystals, respectively). They are periodic along this axis and quasiperiodic in planes normal to it. The second type, icosahedral quasicrystals, are aperiodic in all directions. Icosahedral quasicrystals have a three dimensional quasiperiodic structure and possess fifteen 2-fold, ten 3-fold and six 5-fold axes in accordance with their icosahedral symmetry.[54]

Quasicrystals fall into three groups of different thermal stability:[55]

Except for the Al–Li–Cu system, all the stable quasicrystals are almost free of defects and disorder, as evidenced by X-ray and electron diffraction revealing peak widths as sharp as those of perfect crystals such as Si. Diffraction patterns exhibit fivefold, threefold, and twofold symmetries, and reflections are arranged quasiperiodically in three dimensions.

The origin of the stabilization mechanism is different for the stable and metastable quasicrystals. Nevertheless, there is a common feature observed in most quasicrystal-forming liquid alloys or their undercooled liquids: a local icosahedral order. The icosahedral order is in equilibrium in the liquid state for the stable quasicrystals, whereas the icosahedral order prevails in the undercooled liquid state for the metastable quasicrystals.

A nanoscale icosahedral phase was formed in Zr-, Cu- and Hf-based bulk metallic glasses alloyed with noble metals.[56]

Most quasicrystals have ceramic-like properties including high thermal and electrical resistance, hardness and brittleness, resistance to corrosion, and non-stick properties.[57] Many metallic quasicrystalline substances are impractical for most applications due to their thermal instability; the Al–Cu–Fe ternary system and the Al–Cu–Fe–Cr and Al–Co–Fe–Cr quaternary systems, thermally stable up to 700 °C, are notable exceptions.

The quasi-ordered droplet crystals could be formed under Dipolar forces in the Bose Einstein condensate.[58] While the softcore Rydberg dressing interaction has forms triangular droplet-crystals,[59] adding a Gaussian peak to the plateau type interaction would form multiple roton unstable points in the Bogoliubov spectrum. Therefore, the excitation around the roton instabilities would grow exponentially and form multiple allowed lattice constants leading to quasi-ordered periodic droplet crystals.[58]

Applications edit

Quasicrystalline substances have potential applications in several forms.

Metallic quasicrystalline coatings can be applied by Thermal spraying or magnetron sputtering. A problem that must be resolved is the tendency for cracking due to the materials' extreme brittleness.[57] The cracking could be suppressed by reducing sample dimensions or coating thickness.[60] Recent studies show typically brittle quasicrystals can exhibit remarkable ductility of over 50% strains at room temperature and sub-micrometer scales (<500 nm).[60]

An application was the use of low-friction Al–Cu–Fe–Cr quasicrystals[61] as a coating for frying pans. Food did not stick to it as much as to stainless steel making the pan moderately non-stick and easy to clean; heat transfer and durability were better than PTFE non-stick cookware and the pan was free from perfluorooctanoic acid (PFOA); the surface was very hard, claimed to be ten times harder than stainless steel, and not harmed by metal utensils or cleaning in a dishwasher; and the pan could withstand temperatures of 1,000 °C (1,800 °F) without harm. However, after an initial introduction the pans were a chrome steel, probably because of the difficulty of controlling thin films of the quasicrystal.[62]

The Nobel citation said that quasicrystals, while brittle, could reinforce steel "like armor". When Shechtman was asked about potential applications of quasicrystals he said that a precipitation-hardened stainless steel is produced that is strengthened by small quasicrystalline particles. It does not corrode and is extremely strong, suitable for razor blades and surgery instruments. The small quasicrystalline particles impede the motion of dislocation in the material.[63]

Quasicrystals were also being used to develop heat insulation, LEDs, diesel engines, and new materials that convert heat to electricity. Shechtman suggested new applications taking advantage of the low coefficient of friction and the hardness of some quasicrystalline materials, for example embedding particles in plastic to make strong, hard-wearing, low-friction plastic gears. The low heat conductivity of some quasicrystals makes them good for heat insulating coatings.[63] One of the special properties of quasicrystals is their smooth surface, which despite the irregular atomic structure, the surface of quasicrystals can be smooth and flat.[64]

Other potential applications include selective solar absorbers for power conversion, broad-wavelength reflectors, and bone repair and prostheses applications where biocompatibility, low friction and corrosion resistance are required. Magnetron sputtering can be readily applied to other stable quasicrystalline alloys such as Al–Pd–Mn.[57]

Non-material science applications edit

Applications in macroscopic engineering have been suggested, building quasi-crystal-like large scale engineering structures, which could have interesting physical properties. Also, aperiodic tiling lattice structures may be used instead of isogrid or honeycomb patterns. None of these seem to have been put to use in practice.[65]

See also edit

  • Aperiodic crystal – Crystal type lacking 3D periodicity
  • Archimedean solid – Polyhedra in which all vertices are the same
  • Crystallography – Scientific study of crystal structures
  • Disordered hyperuniformity – A state similar to a liquid and a crystal in properties.
  • Fibonacci quasicrystal – Binary sequence from Fibonacci recurrence
  • Fiveling – Five crystals arranged round a common axis
  • Icosahedral twins – Structure found in atomic clusters and nanoparticles
  • Phason – Collective excitation in aperiodic materials
  • Tessellation – Tiling of a plane in mathematics
  • Time crystal – Structure that repeats in time; a novel type or phase of non-equilibrium matter

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External links edit

  • (1996–2008).
  • What is... a Quasicrystal?, Notices of the AMS 2006, Volume 53, Number 8
  • Gateways towards quasicrystals: a short history by P. Kramer
  • Quasicrystals: an introduction by R. Lifshitz
  • Quasicrystals: an introduction by S. Weber
  • Steinhardt's proposal 2016-10-18 at the Wayback Machine
  • Quasicrystal Research – Documentary 2011 on the research of the University of Stuttgart
  • Thiel, P.A. (2008). "Quasicrystal Surfaces". Annual Review of Physical Chemistry. 59: 129–152. Bibcode:2008ARPC...59..129T. doi:10.1146/annurev.physchem.59.032607.093736. PMID 17988201.
  • "Indiana Steinhardt and the Quest for Quasicrystals – A Conversation with Paul Steinhardt" 2016-11-04 at the Wayback Machine, Ideas Roadshow, 2016
  • Shaginyan, V. R.; Msezane, A. Z.; Popov, K. G.; Japaridze, G. S.; Khodel, V. A. (2013). "Common quantum phase transition in quasicrystals and heavy-fermion metals". Physical Review B. 87 (24): 245122. arXiv:1302.1806. Bibcode:2013PhRvB..87x5122S. doi:10.1103/PhysRevB.87.245122. S2CID 119239115.
  • BBC webpage showing pictures of Quasicrystals
  • Quasicrystal Blocks: Description and Cut & Fold Instructions Space-filling models

April 26, 2024
quasicrystal, confused, with, quasi, crystals, supramolecular, quasiperiodic, crystal, quasicrystal, structure, that, ordered, periodic, quasicrystalline, pattern, continuously, fill, available, space, lacks, translational, symmetry, while, crystals, according. Not to be confused with Quasi crystals supramolecular A quasiperiodic crystal or quasicrystal is a structure that is ordered but not periodic A quasicrystalline pattern can continuously fill all available space but it lacks translational symmetry 2 While crystals according to the classical crystallographic restriction theorem can possess only two three four and six fold rotational symmetries the Bragg diffraction pattern of quasicrystals shows sharp peaks with other symmetry orders for instance five fold 3 Potential energy surface for silver depositing on an aluminium palladium manganese Al Pd Mn quasicrystal surface Similar to Fig 6 in Ref 1 Aperiodic tilings were discovered by mathematicians in the early 1960s and some twenty years later they were found to apply to the study of natural quasicrystals The discovery of these aperiodic forms in nature has produced a paradigm shift in the field of crystallography In crystallography the quasicrystals were predicted in 1981 by a five fold symmetry study of Alan Lindsay Mackay 4 that also brought in 1982 with the crystallographic Fourier transform of a Penrose tiling 5 the possibility of identifying quasiperiodic order in a material through diffraction Quasicrystals had been investigated and observed earlier 6 but until the 1980s they were disregarded in favor of the prevailing views about the atomic structure of matter In 2009 after a dedicated search a mineralogical finding icosahedrite offered evidence for the existence of natural quasicrystals 7 Roughly an ordering is non periodic if it lacks translational symmetry which means that a shifted copy will never match exactly with its original The more precise mathematical definition is that there is never translational symmetry in more than n 1 linearly independent directions where n is the dimension of the space filled e g the three dimensional tiling displayed in a quasicrystal may have translational symmetry in two directions Symmetrical diffraction patterns result from the existence of an indefinitely large number of elements with a regular spacing a property loosely described as long range order Experimentally the aperiodicity is revealed in the unusual symmetry of the diffraction pattern that is symmetry of orders other than two three four or six In 1982 materials scientist Dan Shechtman observed that certain aluminium manganese alloys produced the unusual diffractograms which today are seen as revelatory of quasicrystal structures Due to fear of the scientific community s reaction it took him two years to publish the results 8 9 for which he was awarded the Nobel Prize in Chemistry in 2011 10 On 25 October 2018 Luca Bindi and Paul Steinhardt were awarded the Aspen Institute 2018 Prize for collaboration and scientific research between Italy and the United States after they discovered icosahedrite the first quasicrystal known to occur naturally Contents 1 History 2 Mathematics 3 Materials science 3 1 Applications 4 Non material science applications 5 See also 6 References 7 External linksHistory edit nbsp Girih tile subdivision found in the decagonal girih pattern on a spandrel from the Darb i Imam shrine Isfahan Iran 1453 C E A subdivision rule to construct perfect quasi crystalline tilings has been identified 11 The first representations of perfect quasicrystalline patterns can be found in several early Islamic works of art and architecture such as the Gunbad i Kabud tomb tower the Darb e Imam shrine and the Al Attarine Madrasa 12 13 On July 16 1945 in Alamogordo New Mexico the Trinity nuclear bomb test produced icosahedral quasicrystals They went unnoticed at the time of the test but were later identified in samples of red Trinitite a glass like substance formed from fused sand and copper transmission lines Identified in 2021 they are the oldest known anthropogenic quasicrystals 14 15 nbsp A Penrose tiling In 1961 Hao Wang asked whether determining if a set of tiles admits a tiling of the plane is an algorithmically unsolvable problem or not He conjectured that it is solvable relying on the hypothesis that every set of tiles that can tile the plane can do it periodically hence it would suffice to try to tile bigger and bigger patterns until obtaining one that tiles periodically Nevertheless two years later his student Robert Berger constructed a set of some 20 000 square tiles now called Wang tiles that can tile the plane but not in a periodic fashion As further aperiodic sets of tiles were discovered sets with fewer and fewer shapes were found In 1974 Roger Penrose discovered a set of just two tiles now referred to as Penrose tiles that produced only non periodic tilings of the plane These tilings displayed instances of fivefold symmetry One year later Alan Mackay showed theoretically that the diffraction pattern from the Penrose tiling had a two dimensional Fourier transform consisting of sharp delta peaks arranged in a fivefold symmetric pattern 16 Around the same time Robert Ammann created a set of aperiodic tiles that produced eightfold symmetry In 1972 de Wolf and van Aalst 17 reported that the diffraction pattern produced by a crystal of sodium carbonate cannot be labeled with three indices but needed one more which implied that the underlying structure had four dimensions in reciprocal space Other puzzling cases have been reported 18 but until the concept of quasicrystal came to be established they were explained away or denied 19 20 Shechtman first observed ten fold electron diffraction patterns in 1982 while conducting a routine study of an aluminium manganese alloy Al6Mn at the US National Bureau of Standards later NIST 21 Shechtman related his observation to Ilan Blech who responded that such diffractions had been seen before 22 23 24 Around that time Shechtman also related his finding to John W Cahn of the NIST who did not offer any explanation and challenged him to solve the observation Shechtman quoted Cahn as saying Danny this material is telling us something and I challenge you to find out what it is 25 The observation of the ten fold diffraction pattern lay unexplained for two years until the spring of 1984 when Blech asked Shechtman to show him his results again A quick study of Shechtman s results showed that the common explanation for a ten fold symmetrical diffraction pattern a type of crystal twinning was ruled out by his experiments Therefore Blech looked for a new structure containing cells connected to each other by defined angles and distances but without translational periodicity He decided to use a computer simulation to calculate the diffraction intensity from a cluster of such a material which he termed as multiple polyhedral and found a ten fold structure similar to what was observed The multiple polyhedral structure was termed later by many researchers as icosahedral glass 26 Shechtman accepted Blech s discovery of a new type of material and chose to publish his observation in a paper entitled The Microstructure of Rapidly Solidified Al6Mn which was written around June 1984 and published in a 1985 edition of Metallurgical Transactions A 27 Meanwhile on seeing the draft of the paper John Cahn suggested that Shechtman s experimental results merit a fast publication in a more appropriate scientific journal Shechtman agreed and in hindsight called this fast publication a winning move This paper published in the Physical Review Letters 9 repeated Shechtman s observation and used the same illustrations as the original paper Originally the new form of matter was dubbed Shechtmanite 28 The term quasicrystal was first used in print by Steinhardt and Levine 2 shortly after Shechtman s paper was published Also in 1985 Ishimasa et al reported twelvefold symmetry in Ni Cr particles 29 Soon eightfold diffraction patterns were recorded in V Ni Si and Cr Ni Si alloys 30 Over the years hundreds of quasicrystals with various compositions and different symmetries have been discovered The first quasicrystalline materials were thermodynamically unstable when heated they formed regular crystals However in 1987 the first of many stable quasicrystals were discovered making it possible to produce large samples for study and applications 31 In 1992 the International Union of Crystallography altered its definition of a crystal reducing it to the ability to produce a clear cut diffraction pattern and acknowledging the possibility of the ordering to be either periodic or aperiodic 8 32 nbsp Atomic image of a micron sized grain of the natural Al71Ni24Fe5 quasicrystal shown in the inset from a Khatyrka meteorite fragment The corresponding diffraction patterns reveal a ten fold symmetry 33 nbsp Electron diffraction pattern of an icosahedral Ho Mg Zn quasicrystal In 2001 Paul Steinhardt of Princeton University hypothesized that quasicrystals could exist in nature and developed a method of recognition inviting all the mineralogical collections of the world to identify any badly cataloged crystals In 2007 Steinhardt received a reply by Luca Bindi who found a quasicrystalline specimen from Khatyrka in the University of Florence Mineralogical Collection The crystal samples were sent to Princeton University for other tests and in late 2009 Steinhardt confirmed its quasicrystalline character This quasicrystal with a composition of Al63Cu24Fe13 was named icosahedrite and it was approved by the International Mineralogical Association in 2010 Analysis indicates it may be meteoritic in origin possibly delivered from a carbonaceous chondrite asteroid In 2011 Bindi Steinhardt and a team of specialists found more icosahedrite samples from Khatyrka 34 A further study of Khatyrka meteorites revealed micron sized grains of another natural quasicrystal which has a ten fold symmetry and a chemical formula of Al71Ni24Fe5 This quasicrystal is stable in a narrow temperature range from 1120 to 1200 K at ambient pressure which suggests that natural quasicrystals are formed by rapid quenching of a meteorite heated during an impact induced shock 33 Shechtman was awarded the Nobel Prize in Chemistry in 2011 for his work on quasicrystals His discovery of quasicrystals revealed a new principle for packing of atoms and molecules stated the Nobel Committee and pointed that this led to a paradigm shift within chemistry 8 35 In 2014 Post of Israel issued a stamp dedicated to quasicrystals and the 2011 Nobel Prize 36 While the first quasicrystals discovered were made out of intermetallic components later on quasicrystals were also discovered in soft matter and molecular systems Soft quasicrystal structures have been found in supramolecular dendrimer liquids 37 and ABC Star Polymers 38 in 2004 and 2007 In 2009 it was found that thin film quasicrystals can be formed by self assembly of uniformly shaped nano sized molecular units at an air liquid interface 39 It was demonstrated that these units can be both inorganic and organic 40 Additionally in the 2010s two dimensional molecular quasicrystals were discovered driven by intermolecular interactions 41 and interface interactions 42 In 2018 chemists from Brown University announced the successful creation of a self constructing lattice structure based on a strangely shaped quantum dot While single component quasicrystal lattices have been previously predicted mathematically and in computer simulations 43 they had not been demonstrated prior to this 44 Mathematics edit nbsp A 5 cube as an orthographic projection into 2D using Petrie polygon basis vectors overlaid on the diffractogram from an icosahedral Ho Mg Zn quasicrystal nbsp A 6 cube projected into the rhombic triacontahedron using the golden ratio in the basis vectors This is used to understand the aperiodic icosahedral structure of quasicrystals There are several ways to mathematically define quasicrystalline patterns One definition the cut and project construction is based on the work of Harald Bohr mathematician brother of Niels Bohr The concept of an almost periodic function also called a quasiperiodic function was studied by Bohr including work of Bohl and Escanglon 45 He introduced the notion of a superspace Bohr showed that quasiperiodic functions arise as restrictions of high dimensional periodic functions to an irrational slice an intersection with one or more hyperplanes and discussed their Fourier point spectrum These functions are not exactly periodic but they are arbitrarily close in some sense as well as being a projection of an exactly periodic function In order that the quasicrystal itself be aperiodic this slice must avoid any lattice plane of the higher dimensional lattice De Bruijn showed that Penrose tilings can be viewed as two dimensional slices of five dimensional hypercubic structures 46 similarly icosahedral quasicrystals in three dimensions are projected from a six dimensional hypercubic lattice as first described by Peter Kramer and Roberto Neri in 1984 47 Equivalently the Fourier transform of such a quasicrystal is nonzero only at a dense set of points spanned by integer multiples of a finite set of basis vectors which are the projections of the primitive reciprocal lattice vectors of the higher dimensional lattice 48 Classical theory of crystals reduces crystals to point lattices where each point is the center of mass of one of the identical units of the crystal The structure of crystals can be analyzed by defining an associated group Quasicrystals on the other hand are composed of more than one type of unit so instead of lattices quasilattices must be used Instead of groups groupoids the mathematical generalization of groups in category theory is the appropriate tool for studying quasicrystals 49 Using mathematics for construction and analysis of quasicrystal structures is a difficult task for most experimentalists Computer modeling based on the existing theories of quasicrystals however greatly facilitated this task Advanced programs have been developed 50 allowing one to construct visualize and analyze quasicrystal structures and their diffraction patterns The aperiodic nature of quasicrystals can also make theoretical studies of physical properties such as electronic structure difficult due to the inapplicability of Bloch s theorem However spectra of quasicrystals can still be computed with error control 51 Study of quasicrystals may shed light on the most basic notions related to the quantum critical point observed in heavy fermion metals Experimental measurements on an Au Al Yb quasicrystal have revealed a quantum critical point defining the divergence of the magnetic susceptibility as temperature tends to zero 52 It is suggested that the electronic system of some quasicrystals is located at a quantum critical point without tuning while quasicrystals exhibit the typical scaling behaviour of their thermodynamic properties and belong to the well known family of heavy fermion metals Materials science edit nbsp Tiling of a plane by regular pentagons is impossible but can be realized on a sphere in the form of pentagonal dodecahedron nbsp A Ho Mg Zn dodecahedral quasicrystal formed as a pentagonal dodecahedron the dual of the icosahedron Unlike the similar pyritohedron shape of some cubic system crystals such as pyrite the quasicrystal has faces that are true regular pentagons nbsp TiMn quasicrystal approximant lattice Since the original discovery by Dan Shechtman hundreds of quasicrystals have been reported and confirmed Quasicrystals are found most often in aluminium alloys Al Li Cu Al Mn Si Al Ni Co Al Pd Mn Al Cu Fe Al Cu V etc but numerous other compositions are also known Cd Yb Ti Zr Ni Zn Mg Ho Zn Mg Sc In Ag Yb Pd U Si etc 53 Two types of quasicrystals are known 50 The first type polygonal dihedral quasicrystals have an axis of 8 10 or 12 fold local symmetry octagonal decagonal or dodecagonal quasicrystals respectively They are periodic along this axis and quasiperiodic in planes normal to it The second type icosahedral quasicrystals are aperiodic in all directions Icosahedral quasicrystals have a three dimensional quasiperiodic structure and possess fifteen 2 fold ten 3 fold and six 5 fold axes in accordance with their icosahedral symmetry 54 Quasicrystals fall into three groups of different thermal stability 55 Stable quasicrystals grown by slow cooling or casting with subsequent annealing Metastable quasicrystals prepared by melt spinning and Metastable quasicrystals formed by the crystallization of the amorphous phase Except for the Al Li Cu system all the stable quasicrystals are almost free of defects and disorder as evidenced by X ray and electron diffraction revealing peak widths as sharp as those of perfect crystals such as Si Diffraction patterns exhibit fivefold threefold and twofold symmetries and reflections are arranged quasiperiodically in three dimensions The origin of the stabilization mechanism is different for the stable and metastable quasicrystals Nevertheless there is a common feature observed in most quasicrystal forming liquid alloys or their undercooled liquids a local icosahedral order The icosahedral order is in equilibrium in the liquid state for the stable quasicrystals whereas the icosahedral order prevails in the undercooled liquid state for the metastable quasicrystals A nanoscale icosahedral phase was formed in Zr Cu and Hf based bulk metallic glasses alloyed with noble metals 56 Most quasicrystals have ceramic like properties including high thermal and electrical resistance hardness and brittleness resistance to corrosion and non stick properties 57 Many metallic quasicrystalline substances are impractical for most applications due to their thermal instability the Al Cu Fe ternary system and the Al Cu Fe Cr and Al Co Fe Cr quaternary systems thermally stable up to 700 C are notable exceptions The quasi ordered droplet crystals could be formed under Dipolar forces in the Bose Einstein condensate 58 While the softcore Rydberg dressing interaction has forms triangular droplet crystals 59 adding a Gaussian peak to the plateau type interaction would form multiple roton unstable points in the Bogoliubov spectrum Therefore the excitation around the roton instabilities would grow exponentially and form multiple allowed lattice constants leading to quasi ordered periodic droplet crystals 58 Applications edit Quasicrystalline substances have potential applications in several forms Metallic quasicrystalline coatings can be applied by Thermal spraying or magnetron sputtering A problem that must be resolved is the tendency for cracking due to the materials extreme brittleness 57 The cracking could be suppressed by reducing sample dimensions or coating thickness 60 Recent studies show typically brittle quasicrystals can exhibit remarkable ductility of over 50 strains at room temperature and sub micrometer scales lt 500 nm 60 An application was the use of low friction Al Cu Fe Cr quasicrystals 61 as a coating for frying pans Food did not stick to it as much as to stainless steel making the pan moderately non stick and easy to clean heat transfer and durability were better than PTFE non stick cookware and the pan was free from perfluorooctanoic acid PFOA the surface was very hard claimed to be ten times harder than stainless steel and not harmed by metal utensils or cleaning in a dishwasher and the pan could withstand temperatures of 1 000 C 1 800 F without harm However after an initial introduction the pans were a chrome steel probably because of the difficulty of controlling thin films of the quasicrystal 62 The Nobel citation said that quasicrystals while brittle could reinforce steel like armor When Shechtman was asked about potential applications of quasicrystals he said that a precipitation hardened stainless steel is produced that is strengthened by small quasicrystalline particles It does not corrode and is extremely strong suitable for razor blades and surgery instruments The small quasicrystalline particles impede the motion of dislocation in the material 63 Quasicrystals were also being used to develop heat insulation LEDs diesel engines and new materials that convert heat to electricity Shechtman suggested new applications taking advantage of the low coefficient of friction and the hardness of some quasicrystalline materials for example embedding particles in plastic to make strong hard wearing low friction plastic gears The low heat conductivity of some quasicrystals makes them good for heat insulating coatings 63 One of the special properties of quasicrystals is their smooth surface which despite the irregular atomic structure the surface of quasicrystals can be smooth and flat 64 Other potential applications include selective solar absorbers for power conversion broad wavelength reflectors and bone repair and prostheses applications where biocompatibility low friction and corrosion resistance are required Magnetron sputtering can be readily applied to other stable quasicrystalline alloys such as Al Pd Mn 57 Non material science applications editApplications in macroscopic engineering have been suggested building quasi crystal like large scale engineering structures which could have interesting physical properties Also aperiodic tiling lattice structures may be used instead of isogrid or honeycomb patterns None of these seem to have been put to use in practice 65 See also editAperiodic crystal Crystal type lacking 3D periodicity Archimedean solid Polyhedra in which all vertices are the same Crystallography Scientific study of crystal structures Disordered hyperuniformity A state similar to a liquid and a crystal in properties Pages displaying wikidata descriptions as a fallback Fibonacci quasicrystal Binary sequence from Fibonacci recurrencePages displaying short descriptions of redirect targets Fiveling Five crystals arranged round a common axis Icosahedral twins Structure found in atomic clusters and nanoparticles Phason Collective excitation in aperiodic materials Tessellation Tiling of a plane in mathematics Time crystal Structure that repeats in time a novel type or phase of non equilibrium matterReferences edit Unal B V Fournee K J Schnitzenbaumer C Ghosh C J Jenks A R Ross T A Lograsso J W Evans P A Thiel 2007 Nucleation and growth of Ag islands on fivefold Al Pd Mn quasicrystal surfaces Dependence of island density on temperature and flux Physical Review B 75 6 064205 Bibcode 2007PhRvB 75f4205U doi 10 1103 PhysRevB 75 064205 S2CID 53382207 a b Levine Dov Steinhardt Paul 1984 Quasicrystals A New Class of Ordered Structures Physical Review Letters 53 26 2477 2480 Bibcode 1984PhRvL 53 2477L doi 10 1103 PhysRevLett 53 2477 Lifshitz Ron Schmid Siegbert Withers Ray L 2013 Aperiodic crystals Springer OCLC 847002667 Alan L Mackay De Nive Quinquangula Krystallografiya Vol 26 910 919 1981 Alan L Mackay Crystallography and the Penrose Pattern Physica 114 A 609 1982 Steurer W 2004 Twenty years of structure research on quasicrystals Part I Pentagonal octagonal decagonal and dodecagonal quasicrystals Z Kristallogr 219 7 2004 391 446 Bibcode 2004ZK 219 391S doi 10 1524 zkri 219 7 391 35643 Bindi L Steinhardt P J Yao N Lu P J 2009 Natural Quasicrystals Science 324 5932 1306 9 Bibcode 2009Sci 324 1306B doi 10 1126 science 1170827 PMID 19498165 S2CID 14512017 a b c Gerlin Andrea October 5 2011 Tecnion s Shechtman Wins Nobel in Chemistry for Quasicrystals Discovery Bloomberg Archived from the original on December 5 2014 Retrieved January 4 2019 a b Shechtman D Blech I Gratias D Cahn J 1984 Metallic Phase with Long Range Orientational Order and No Translational Symmetry Physical Review Letters 53 20 1951 1953 Bibcode 1984PhRvL 53 1951S doi 10 1103 PhysRevLett 53 1951 The Nobel Prize in Chemistry 2011 Nobelprize org Retrieved 2011 10 06 Lu Peter J Steinhardt Paul J 2007 02 23 Decagonal and Quasi Crystalline Tilings in Medieval Islamic Architecture Science 315 5815 1106 1110 Bibcode 2007Sci 315 1106L doi 10 1126 science 1135491 ISSN 0036 8075 PMID 17322056 S2CID 10374218 Al Ajlouni Rima 2013 Octagon Based Quasicrystalline Formations in Islamic Architecture In Schmid Siegbert Withers Ray L Lifshitz Ron eds Aperiodic Crystals Dordrecht Springer Netherlands pp 49 57 doi 10 1007 978 94 007 6431 6 7 ISBN 978 94 007 6431 6 Islamic Quasicrystal Tilings Paul J Steinhardt paulsteinhardt org Retrieved 2023 05 29 Bindi Luca 2021 06 01 Accidental synthesis of a previously unknown quasicrystal in the first atomic bomb test Proceedings of the National Academy of Sciences 118 22 e2101350118 Bibcode 2021PNAS 11801350B doi 10 1073 pnas 2101350118 PMC 8179242 PMID 34001665 Mullane Laura May 18 2021 Newly discovered quasicrystal was created by the first nuclear explosion at Trinity Site Phys org Retrieved May 21 2021 Mackay A L 1982 Crystallography and the Penrose Pattern Physica A 114 1 609 613 Bibcode 1982PhyA 114 609M doi 10 1016 0378 4371 82 90359 4 de Wolf R M amp van Aalst W 1972 The four dimensional group of g Na2CO3 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Quest for Quasicrystals A Conversation with Paul Steinhardt Archived 2016 11 04 at the Wayback Machine Ideas Roadshow 2016 Shaginyan V R Msezane A Z Popov K G Japaridze G S Khodel V A 2013 Common quantum phase transition in quasicrystals and heavy fermion metals Physical Review B 87 24 245122 arXiv 1302 1806 Bibcode 2013PhRvB 87x5122S doi 10 1103 PhysRevB 87 245122 S2CID 119239115 BBC webpage showing pictures of Quasicrystals Quasicrystal Blocks Description and Cut amp Fold Instructions Space filling models Retrieved from https en wikipedia org w index php title Quasicrystal amp oldid 1220490957, wikipedia, wiki, book, books, library,

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