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Crystallographic defect

January 01, 1970

A crystallographic defect is an interruption of the regular patterns of arrangement of atoms or molecules in crystalline solids. The positions and orientations of particles, which are repeating at fixed distances determined by the unit cell parameters in crystals, exhibit a periodic crystal structure, but this is usually imperfect.[2][3][4][5] Several types of defects are often characterized: point defects, line defects, planar defects, bulk defects. Topological homotopy establishes a mathematical method of characterization.

Electron microscopy of antisites (a, Mo substitutes for S) and vacancies (b, missing S atoms) in a monolayer of molybdenum disulfide. Scale bar: 1 nm.[1]

Point defects edit

Point defects are defects that occur only at or around a single lattice point. They are not extended in space in any dimension. Strict limits for how small a point defect is are generally not defined explicitly. However, these defects typically involve at most a few extra or missing atoms. Larger defects in an ordered structure are usually considered dislocation loops. For historical reasons, many point defects, especially in ionic crystals, are called centers: for example a vacancy in many ionic solids is called a luminescence center, a color center, or F-center. These dislocations permit ionic transport through crystals leading to electrochemical reactions. These are frequently specified using Kröger–Vink notation.

  • Vacancy defects are lattice sites which would be occupied in a perfect crystal, but are vacant. If a neighboring atom moves to occupy the vacant site, the vacancy moves in the opposite direction to the site which used to be occupied by the moving atom. The stability of the surrounding crystal structure guarantees that the neighboring atoms will not simply collapse around the vacancy. In some materials, neighboring atoms actually move away from a vacancy, because they experience attraction from atoms in the surroundings. A vacancy (or pair of vacancies in an ionic solid) is sometimes called a Schottky defect.
  • Interstitial defects are atoms that occupy a site in the crystal structure at which there is usually not an atom. They are generally high energy configurations. Small atoms (mostly impurities) in some crystals can occupy interstices without high energy, such as hydrogen in palladium.
 
Schematic illustration of some simple point defect types in a monatomic solid
  • A nearby pair of a vacancy and an interstitial is often called a Frenkel defect or Frenkel pair. This is caused when an ion moves into an interstitial site and creates a vacancy.

  • Due to fundamental limitations of material purification methods, materials are never 100% pure, which by definition induces defects in crystal structure. In the case of an impurity, the atom is often incorporated at a regular atomic site in the crystal structure. This is neither a vacant site nor is the atom on an interstitial site and it is called a substitutional defect. The atom is not supposed to be anywhere in the crystal, and is thus an impurity. In some cases where the radius of the substitutional atom (ion) is substantially smaller than that of the atom (ion) it is replacing, its equilibrium position can be shifted away from the lattice site. These types of substitutional defects are often referred to as off-center ions. There are two different types of substitutional defects: Isovalent substitution and aliovalent substitution. Isovalent substitution is where the ion that is substituting the original ion is of the same oxidation state as the ion it is replacing. Aliovalent substitution is where the ion that is substituting the original ion is of a different oxidation state than the ion it is replacing. Aliovalent substitutions change the overall charge within the ionic compound, but the ionic compound must be neutral. Therefore, a charge compensation mechanism is required. Hence either one of the metals is partially or fully oxidised or reduced, or ion vacancies are created.
  • Antisite defects[6][7] occur in an ordered alloy or compound when atoms of different type exchange positions. For example, some alloys have a regular structure in which every other atom is a different species; for illustration assume that type A atoms sit on the corners of a cubic lattice, and type B atoms sit in the center of the cubes. If one cube has an A atom at its center, the atom is on a site usually occupied by a B atom, and is thus an antisite defect. This is neither a vacancy nor an interstitial, nor an impurity.
  • Topological defects are regions in a crystal where the normal chemical bonding environment is topologically different from the surroundings. For instance, in a perfect sheet of graphite (graphene) all atoms are in rings containing six atoms. If the sheet contains regions where the number of atoms in a ring is different from six, while the total number of atoms remains the same, a topological defect has formed. An example is the Stone Wales defect in nanotubes, which consists of two adjacent 5-membered and two 7-membered atom rings.
 
Schematic illustration of defects in a compound solid, using GaAs as an example.
  • Amorphous solids may contain defects. These are naturally somewhat hard to define, but sometimes their nature can be quite easily understood. For instance, in ideally bonded amorphous silica all Si atoms have 4 bonds to O atoms and all O atoms have 2 bonds to Si atom. Thus e.g. an O atom with only one Si bond (a dangling bond) can be considered a defect in silica.[8] Moreover, defects can also be defined in amorphous solids based on empty or densely packed local atomic neighbourhoods, and the properties of such 'defects' can be shown to be similar to normal vacancies and interstitials in crystals.[9][10][11]
  • Complexes can form between different kinds of point defects. For example, if a vacancy encounters an impurity, the two may bind together if the impurity is too large for the lattice. Interstitials can form 'split interstitial' or 'dumbbell' structures where two atoms effectively share an atomic site, resulting in neither atom actually occupying the site.[12][13]

Line defects edit

Line defects can be described by gauge theories.

Dislocations are linear defects, around which the atoms of the crystal lattice are misaligned.[14] There are two basic types of dislocations, the edge dislocation and the screw dislocation. "Mixed" dislocations, combining aspects of both types, are also common.

 
An edge dislocation is shown. The dislocation line is presented in blue, the Burgers vector b in black.

Edge dislocations are caused by the termination of a plane of atoms in the middle of a crystal. In such a case, the adjacent planes are not straight, but instead bend around the edge of the terminating plane so that the crystal structure is perfectly ordered on either side. The analogy with a stack of paper is apt: if a half a piece of paper is inserted in a stack of paper, the defect in the stack is only noticeable at the edge of the half sheet.

The screw dislocation is more difficult to visualise, but basically comprises a structure in which a helical path is traced around the linear defect (dislocation line) by the atomic planes of atoms in the crystal lattice.

The presence of dislocation results in lattice strain (distortion). The direction and magnitude of such distortion is expressed in terms of a Burgers vector (b). For an edge type, b is perpendicular to the dislocation line, whereas in the cases of the screw type it is parallel. In metallic materials, b is aligned with close-packed crystallographic directions and its magnitude is equivalent to one interatomic spacing.

Dislocations can move if the atoms from one of the surrounding planes break their bonds and rebond with the atoms at the terminating edge.

It is the presence of dislocations and their ability to readily move (and interact) under the influence of stresses induced by external loads that leads to the characteristic malleability of metallic materials.

Dislocations can be observed using transmission electron microscopy, field ion microscopy and atom probe techniques. Deep-level transient spectroscopy has been used for studying the electrical activity of dislocations in semiconductors, mainly silicon.

Disclinations are line defects corresponding to "adding" or "subtracting" an angle around a line. Basically, this means that if you track the crystal orientation around the line defect, you get a rotation. Usually, they were thought to play a role only in liquid crystals, but recent developments suggest that they might have a role also in solid materials, e.g. leading to the self-healing of cracks.[15]

Planar defects edit

 
Origin of stacking faults: Different stacking sequences of close-packed crystals
  • Grain boundaries occur where the crystallographic direction of the lattice abruptly changes. This usually occurs when two crystals begin growing separately and then meet.
  • Antiphase boundaries occur in ordered alloys: in this case, the crystallographic direction remains the same, but each side of the boundary has an opposite phase: For example, if the ordering is usually ABABABAB (hexagonal close-packed crystal), an antiphase boundary takes the form of ABABBABA.
  • Stacking faults occur in a number of crystal structures, but the common example is in close-packed structures. They are formed by a local deviation of the stacking sequence of layers in a crystal. An example would be the ABABCABAB stacking sequence.
  • A twin boundary is a defect that introduces a plane of mirror symmetry in the ordering of a crystal. For example, in cubic close-packed crystals, the stacking sequence of a twin boundary would be ABCABCBACBA.
  • On planes of single crystals, steps between atomically flat terraces can also be regarded as planar defects. It has been shown that such defects and their geometry have significant influence on the adsorption of organic molecules[16]

Bulk defects edit

  • Three-dimensional macroscopic or bulk defects, such as pores, cracks, or inclusions
  • Voids — small regions where there are no atoms, and which can be thought of as clusters of vacancies
  • Impurities can cluster together to form small regions of a different phase. These are often called precipitates.

Mathematical classification methods edit

A successful mathematical classification method for physical lattice defects, which works not only with the theory of dislocations and other defects in crystals but also, e.g., for disclinations in liquid crystals and for excitations in superfluid 3He, is the topological homotopy theory.[17]

Computer simulation methods edit

Density functional theory, classical molecular dynamics and kinetic Monte Carlo[18] simulations are widely used to study the properties of defects in solids with computer simulations.[9][10][11][19][20][21][22] Simulating jamming of hard spheres of different sizes and/or in containers with non-commeasurable sizes using the Lubachevsky–Stillinger algorithm can be an effective technique for demonstrating some types of crystallographic defects.[23]

See also edit

References edit

  1. ^ Hong, J.; Hu, Z.; Probert, M.; Li, K.; Lv, D.; Yang, X.; Gu, L.; Mao, N.; Feng, Q.; Xie, L.; Zhang, J.; Wu, D.; Zhang, Z.; Jin, C.; Ji, W.; Zhang, X.; Yuan, J.; Zhang, Z. (2015). "Exploring atomic defects in molybdenum disulphide monolayers". Nature Communications. 6: 6293. Bibcode:2015NatCo...6.6293H. doi:10.1038/ncomms7293. PMC 4346634. PMID 25695374.
  2. ^ Ehrhart, P. (1991) Properties and interactions of atomic defects in metals and alloys Archived 2013-02-03 at archive.today, volume 25 of Landolt-Börnstein, New Series III, chapter 2, p. 88, Springer, Berlin
  3. ^ Siegel, R. W. (1982) Atomic Defects and Diffusion in Metals, in Point Defects and Defect Interactions in Metals, J.-I. Takamura (ED.), p. 783, North Holland, Amsterdam
  4. ^ Crawford, J. H.; Slifkin, L. M., eds. (1975). Point Defects in Solids. New York: Plenum Press.
  5. ^ Watkins, G. D. (1997) "Native defects and their interactions with impurities in silicon", p. 139 in Defects and Diffusion in Silicon Processing, T. Diaz de la Rubia, S. Coffa, P. A. Stolk, and C. S. Rafferty (eds), vol. 469 of MRS Symposium Proceedings, Materials Research Society, Pittsburgh, ISBN 1-55899-373-8
  6. ^ Mattila, T; Nieminen, RM (1995). "Direct Antisite Formation in Electron Irradiation of GaAs". Physical Review Letters. 74 (14): 2721–2724. Bibcode:1995PhRvL..74.2721M. doi:10.1103/PhysRevLett.74.2721. PMID 10058001.
  7. ^ Hausmann, H.; Pillukat, A.; Ehrhart, P. (1996). "Point defects and their reactions in electron-irradiated GaAs investigated by optical absorption spectroscopy". Physical Review B. 54 (12): 8527–8539. Bibcode:1996PhRvB..54.8527H. doi:10.1103/PhysRevB.54.8527. PMID 9984528.
  8. ^ Lieb, Klaus-Peter; Keinonen, Juhani (2006). "Luminescence of ion-irradiated α-quartz". Contemporary Physics. 47 (5): 305–331. Bibcode:2006ConPh..47..305L. doi:10.1080/00107510601088156. S2CID 119348046.
  9. ^ a b Ashkenazy, Yinon; Averback, Robert S. (2012). "Irradiation Induced Grain Boundary Flow—A New Creep Mechanism at the Nanoscale". Nano Letters. 12 (8): 4084–9. Bibcode:2012NanoL..12.4084A. doi:10.1021/nl301554k. PMID 22775230.
  10. ^ a b Mayr, S.; Ashkenazy, Y.; Albe, K.; Averback, R. (2003). "Mechanisms of radiation-induced viscous flow: Role of point defects". Phys. Rev. Lett. 90 (5): 055505. Bibcode:2003PhRvL..90e5505M. doi:10.1103/PhysRevLett.90.055505. PMID 12633371.
  11. ^ a b Nordlund, K; Ashkenazy, Y; Averback, R. S; Granato, A. V (2005). "Strings and interstitials in liquids, glasses and crystals". Europhys. Lett. 71 (4): 625–631. Bibcode:2005EL.....71..625N. doi:10.1209/epl/i2005-10132-1. S2CID 250805987.
  12. ^ Hannes Raebiger (2010). "Theory of defect complexes in insulators". Physical Review B. 82 (7): 073104. Bibcode:2010PhRvB..82g3104R. doi:10.1103/PhysRevB.82.073104.
  13. ^ Hannes Raebiger, Hikaru Nakayama, and Takeshi Fujita (2014). "Control of defect binding and magnetic interaction energies in dilute magnetic semiconductors by charge state manipulation". Journal of Applied Physics. 115 (1): 012008. Bibcode:2014JAP...115a2008R. doi:10.1063/1.4838016.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  14. ^ Hirth, J. P.; Lothe, J. (1992). Theory of dislocations (2 ed.). Krieger Pub Co. ISBN 978-0-89464-617-1.
  15. ^ "Chandler, David L., Cracked metal, heal thyself, MIT news, October 9, 2013".
  16. ^ Waldmann, T. (2012). "The role of surface defects in large organic molecule adsorption: substrate configuration effects". Physical Chemistry Chemical Physics. 14 (30): 10726–31. Bibcode:2012PCCP...1410726W. doi:10.1039/C2CP40800G. PMID 22751288.
  17. ^ Mermin, N. (1979). "The topological theory of defects in ordered media". Reviews of Modern Physics. 51 (3): 591–648. Bibcode:1979RvMP...51..591M. doi:10.1103/RevModPhys.51.591.
  18. ^ Cai, W.; Bulatov, V. V.; Justo, J. F.; Argon, A.S; Yip, S. (2000). "Intrinsic mobility of a dissociated dislocation in silicon". Phys. Rev. Lett. 84 (15): 3346–3349. Bibcode:2000PhRvL..84.3346C. doi:10.1103/PhysRevLett.84.3346. PMID 11019086.
  19. ^ Korhonen, T; Puska, M.; Nieminen, R. (1995). "Vacancy formation energies for fcc and bcc transition metals". Phys. Rev. B. 51 (15): 9526–9532. Bibcode:1995PhRvB..51.9526K. doi:10.1103/PhysRevB.51.9526. PMID 9977614.
  20. ^ Puska, M. J.; Pöykkö, S.; Pesola, M.; Nieminen, R. (1998). "Convergence of supercell calculations for point defects in semiconductors: vacancy in silicon". Phys. Rev. B. 58 (3): 1318–1325. Bibcode:1998PhRvB..58.1318P. doi:10.1103/PhysRevB.58.1318.
  21. ^ Nordlund, K.; Averback, R. (1998). "The role of self-interstitial atoms on the high temperature properties of metals". Phys. Rev. Lett. 80 (19): 4201–4204. Bibcode:1998PhRvL..80.4201N. doi:10.1103/PhysRevLett.80.4201.
  22. ^ Sadigh, B; Lenosky, Thomas; Theiss, Silva; Caturla, Maria-Jose; Diaz De La Rubia, Tomas; Foad, Majeed (1999). "Mechanism of Boron Diffusion in Silicon: An Ab Initio and Kinetic Monte Carlo Study". Phys. Rev. Lett. 83 (21): 4341–4344. Bibcode:1999PhRvL..83.4341S. doi:10.1103/PhysRevLett.83.4341.
  23. ^ Stillinger, Frank H.; Lubachevsky, Boris D. (1995). "Patterns of broken symmetry in the impurity-perturbed rigid-disk crystal". Journal of Statistical Physics. 78 (3–4): 1011–1026. Bibcode:1995JSP....78.1011S. doi:10.1007/BF02183698. S2CID 55943037.

Further reading edit

January 01, 1970
crystallographic, defect, crystallographic, defect, interruption, regular, patterns, arrangement, atoms, molecules, crystalline, solids, positions, orientations, particles, which, repeating, fixed, distances, determined, unit, cell, parameters, crystals, exhib. A crystallographic defect is an interruption of the regular patterns of arrangement of atoms or molecules in crystalline solids The positions and orientations of particles which are repeating at fixed distances determined by the unit cell parameters in crystals exhibit a periodic crystal structure but this is usually imperfect 2 3 4 5 Several types of defects are often characterized point defects line defects planar defects bulk defects Topological homotopy establishes a mathematical method of characterization Electron microscopy of antisites a Mo substitutes for S and vacancies b missing S atoms in a monolayer of molybdenum disulfide Scale bar 1 nm 1 Contents 1 Point defects 2 Line defects 3 Planar defects 4 Bulk defects 5 Mathematical classification methods 6 Computer simulation methods 7 See also 8 References 9 Further readingPoint defects editPoint defects are defects that occur only at or around a single lattice point They are not extended in space in any dimension Strict limits for how small a point defect is are generally not defined explicitly However these defects typically involve at most a few extra or missing atoms Larger defects in an ordered structure are usually considered dislocation loops For historical reasons many point defects especially in ionic crystals are called centers for example a vacancy in many ionic solids is called a luminescence center a color center or F center These dislocations permit ionic transport through crystals leading to electrochemical reactions These are frequently specified using Kroger Vink notation Vacancy defects are lattice sites which would be occupied in a perfect crystal but are vacant If a neighboring atom moves to occupy the vacant site the vacancy moves in the opposite direction to the site which used to be occupied by the moving atom The stability of the surrounding crystal structure guarantees that the neighboring atoms will not simply collapse around the vacancy In some materials neighboring atoms actually move away from a vacancy because they experience attraction from atoms in the surroundings A vacancy or pair of vacancies in an ionic solid is sometimes called a Schottky defect Interstitial defects are atoms that occupy a site in the crystal structure at which there is usually not an atom They are generally high energy configurations Small atoms mostly impurities in some crystals can occupy interstices without high energy such as hydrogen in palladium nbsp Schematic illustration of some simple point defect types in a monatomic solid A nearby pair of a vacancy and an interstitial is often called a Frenkel defect or Frenkel pair This is caused when an ion moves into an interstitial site and creates a vacancy Due to fundamental limitations of material purification methods materials are never 100 pure which by definition induces defects in crystal structure In the case of an impurity the atom is often incorporated at a regular atomic site in the crystal structure This is neither a vacant site nor is the atom on an interstitial site and it is called a substitutional defect The atom is not supposed to be anywhere in the crystal and is thus an impurity In some cases where the radius of the substitutional atom ion is substantially smaller than that of the atom ion it is replacing its equilibrium position can be shifted away from the lattice site These types of substitutional defects are often referred to as off center ions There are two different types of substitutional defects Isovalent substitution and aliovalent substitution Isovalent substitution is where the ion that is substituting the original ion is of the same oxidation state as the ion it is replacing Aliovalent substitution is where the ion that is substituting the original ion is of a different oxidation state than the ion it is replacing Aliovalent substitutions change the overall charge within the ionic compound but the ionic compound must be neutral Therefore a charge compensation mechanism is required Hence either one of the metals is partially or fully oxidised or reduced or ion vacancies are created Antisite defects 6 7 occur in an ordered alloy or compound when atoms of different type exchange positions For example some alloys have a regular structure in which every other atom is a different species for illustration assume that type A atoms sit on the corners of a cubic lattice and type B atoms sit in the center of the cubes If one cube has an A atom at its center the atom is on a site usually occupied by a B atom and is thus an antisite defect This is neither a vacancy nor an interstitial nor an impurity Topological defects are regions in a crystal where the normal chemical bonding environment is topologically different from the surroundings For instance in a perfect sheet of graphite graphene all atoms are in rings containing six atoms If the sheet contains regions where the number of atoms in a ring is different from six while the total number of atoms remains the same a topological defect has formed An example is the Stone Wales defect in nanotubes which consists of two adjacent 5 membered and two 7 membered atom rings nbsp Schematic illustration of defects in a compound solid using GaAs as an example Amorphous solids may contain defects These are naturally somewhat hard to define but sometimes their nature can be quite easily understood For instance in ideally bonded amorphous silica all Si atoms have 4 bonds to O atoms and all O atoms have 2 bonds to Si atom Thus e g an O atom with only one Si bond a dangling bond can be considered a defect in silica 8 Moreover defects can also be defined in amorphous solids based on empty or densely packed local atomic neighbourhoods and the properties of such defects can be shown to be similar to normal vacancies and interstitials in crystals 9 10 11 Complexes can form between different kinds of point defects For example if a vacancy encounters an impurity the two may bind together if the impurity is too large for the lattice Interstitials can form split interstitial or dumbbell structures where two atoms effectively share an atomic site resulting in neither atom actually occupying the site 12 13 Line defects editLine defects can be described by gauge theories Dislocations are linear defects around which the atoms of the crystal lattice are misaligned 14 There are two basic types of dislocations the edge dislocation and the screw dislocation Mixed dislocations combining aspects of both types are also common nbsp An edge dislocation is shown The dislocation line is presented in blue the Burgers vector b in black Edge dislocations are caused by the termination of a plane of atoms in the middle of a crystal In such a case the adjacent planes are not straight but instead bend around the edge of the terminating plane so that the crystal structure is perfectly ordered on either side The analogy with a stack of paper is apt if a half a piece of paper is inserted in a stack of paper the defect in the stack is only noticeable at the edge of the half sheet The screw dislocation is more difficult to visualise but basically comprises a structure in which a helical path is traced around the linear defect dislocation line by the atomic planes of atoms in the crystal lattice The presence of dislocation results in lattice strain distortion The direction and magnitude of such distortion is expressed in terms of a Burgers vector b For an edge type b is perpendicular to the dislocation line whereas in the cases of the screw type it is parallel In metallic materials b is aligned with close packed crystallographic directions and its magnitude is equivalent to one interatomic spacing Dislocations can move if the atoms from one of the surrounding planes break their bonds and rebond with the atoms at the terminating edge It is the presence of dislocations and their ability to readily move and interact under the influence of stresses induced by external loads that leads to the characteristic malleability of metallic materials Dislocations can be observed using transmission electron microscopy field ion microscopy and atom probe techniques Deep level transient spectroscopy has been used for studying the electrical activity of dislocations in semiconductors mainly silicon Disclinations are line defects corresponding to adding or subtracting an angle around a line Basically this means that if you track the crystal orientation around the line defect you get a rotation Usually they were thought to play a role only in liquid crystals but recent developments suggest that they might have a role also in solid materials e g leading to the self healing of cracks 15 Planar defects edit nbsp Origin of stacking faults Different stacking sequences of close packed crystals Grain boundaries occur where the crystallographic direction of the lattice abruptly changes This usually occurs when two crystals begin growing separately and then meet Antiphase boundaries occur in ordered alloys in this case the crystallographic direction remains the same but each side of the boundary has an opposite phase For example if the ordering is usually ABABABAB hexagonal close packed crystal an antiphase boundary takes the form of ABABBABA Stacking faults occur in a number of crystal structures but the common example is in close packed structures They are formed by a local deviation of the stacking sequence of layers in a crystal An example would be the ABABCABAB stacking sequence A twin boundary is a defect that introduces a plane of mirror symmetry in the ordering of a crystal For example in cubic close packed crystals the stacking sequence of a twin boundary would be ABCABCBACBA On planes of single crystals steps between atomically flat terraces can also be regarded as planar defects It has been shown that such defects and their geometry have significant influence on the adsorption of organic molecules 16 Bulk defects editThree dimensional macroscopic or bulk defects such as pores cracks or inclusions Voids small regions where there are no atoms and which can be thought of as clusters of vacancies Impurities can cluster together to form small regions of a different phase These are often called precipitates Mathematical classification methods editA successful mathematical classification method for physical lattice defects which works not only with the theory of dislocations and other defects in crystals but also e g for disclinations in liquid crystals and for excitations in superfluid 3He is the topological homotopy theory 17 Computer simulation methods editDensity functional theory classical molecular dynamics and kinetic Monte Carlo 18 simulations are widely used to study the properties of defects in solids with computer simulations 9 10 11 19 20 21 22 Simulating jamming of hard spheres of different sizes and or in containers with non commeasurable sizes using the Lubachevsky Stillinger algorithm can be an effective technique for demonstrating some types of crystallographic defects 23 See also editBjerrum defect Crystallographic defects in diamond Kroger Vink notation F centerReferences edit Hong J Hu Z Probert M Li K Lv D Yang X Gu L Mao N Feng Q Xie L Zhang J Wu D Zhang Z Jin C Ji W Zhang X Yuan J Zhang Z 2015 Exploring atomic defects in molybdenum disulphide monolayers Nature Communications 6 6293 Bibcode 2015NatCo 6 6293H doi 10 1038 ncomms7293 PMC 4346634 PMID 25695374 Ehrhart P 1991 Properties and interactions of atomic defects in metals and alloys Archived 2013 02 03 at archive today volume 25 of Landolt Bornstein New Series III chapter 2 p 88 Springer Berlin Siegel R W 1982 Atomic Defects and Diffusion in Metals in Point Defects and Defect Interactions in Metals J I Takamura ED p 783 North Holland Amsterdam Crawford J H Slifkin L M eds 1975 Point Defects in Solids New York Plenum Press Watkins G D 1997 Native defects and their interactions with impurities in silicon p 139 in Defects and Diffusion in Silicon Processing T Diaz de la Rubia S Coffa P A Stolk and C S Rafferty eds vol 469 of MRS Symposium Proceedings Materials Research Society Pittsburgh ISBN 1 55899 373 8 Mattila T Nieminen RM 1995 Direct Antisite Formation in Electron Irradiation of GaAs Physical Review Letters 74 14 2721 2724 Bibcode 1995PhRvL 74 2721M doi 10 1103 PhysRevLett 74 2721 PMID 10058001 Hausmann H Pillukat A Ehrhart P 1996 Point defects and their reactions in electron irradiated GaAs investigated by optical absorption spectroscopy Physical Review B 54 12 8527 8539 Bibcode 1996PhRvB 54 8527H doi 10 1103 PhysRevB 54 8527 PMID 9984528 Lieb Klaus Peter Keinonen Juhani 2006 Luminescence of ion irradiated a quartz Contemporary Physics 47 5 305 331 Bibcode 2006ConPh 47 305L doi 10 1080 00107510601088156 S2CID 119348046 a b Ashkenazy Yinon Averback Robert S 2012 Irradiation Induced Grain Boundary Flow A New Creep Mechanism at the Nanoscale Nano Letters 12 8 4084 9 Bibcode 2012NanoL 12 4084A doi 10 1021 nl301554k PMID 22775230 a b Mayr S Ashkenazy Y Albe K Averback R 2003 Mechanisms of radiation induced viscous flow Role of point defects Phys Rev Lett 90 5 055505 Bibcode 2003PhRvL 90e5505M doi 10 1103 PhysRevLett 90 055505 PMID 12633371 a b Nordlund K Ashkenazy Y Averback R S Granato A V 2005 Strings and interstitials in liquids glasses and crystals Europhys Lett 71 4 625 631 Bibcode 2005EL 71 625N doi 10 1209 epl i2005 10132 1 S2CID 250805987 Hannes Raebiger 2010 Theory of defect complexes in insulators Physical Review B 82 7 073104 Bibcode 2010PhRvB 82g3104R doi 10 1103 PhysRevB 82 073104 Hannes Raebiger Hikaru Nakayama and Takeshi Fujita 2014 Control of defect binding and magnetic interaction energies in dilute magnetic semiconductors by charge state manipulation Journal of Applied Physics 115 1 012008 Bibcode 2014JAP 115a2008R doi 10 1063 1 4838016 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Hirth J P Lothe J 1992 Theory of dislocations 2 ed Krieger Pub Co ISBN 978 0 89464 617 1 Chandler David L Cracked metal heal thyself MIT news October 9 2013 Waldmann T 2012 The role of surface defects in large organic molecule adsorption substrate configuration effects Physical Chemistry Chemical Physics 14 30 10726 31 Bibcode 2012PCCP 1410726W doi 10 1039 C2CP40800G PMID 22751288 Mermin N 1979 The topological theory of defects in ordered media Reviews of Modern Physics 51 3 591 648 Bibcode 1979RvMP 51 591M doi 10 1103 RevModPhys 51 591 Cai W Bulatov V V Justo J F Argon A S Yip S 2000 Intrinsic mobility of a dissociated dislocation in silicon Phys Rev Lett 84 15 3346 3349 Bibcode 2000PhRvL 84 3346C doi 10 1103 PhysRevLett 84 3346 PMID 11019086 Korhonen T Puska M Nieminen R 1995 Vacancy formation energies for fcc and bcc transition metals Phys Rev B 51 15 9526 9532 Bibcode 1995PhRvB 51 9526K doi 10 1103 PhysRevB 51 9526 PMID 9977614 Puska M J Poykko S Pesola M Nieminen R 1998 Convergence of supercell calculations for point defects in semiconductors vacancy in silicon Phys Rev B 58 3 1318 1325 Bibcode 1998PhRvB 58 1318P doi 10 1103 PhysRevB 58 1318 Nordlund K Averback R 1998 The role of self interstitial atoms on the high temperature properties of metals Phys Rev Lett 80 19 4201 4204 Bibcode 1998PhRvL 80 4201N doi 10 1103 PhysRevLett 80 4201 Sadigh B Lenosky Thomas Theiss Silva Caturla Maria Jose Diaz De La Rubia Tomas Foad Majeed 1999 Mechanism of Boron Diffusion in Silicon An Ab Initio and Kinetic Monte Carlo Study Phys Rev Lett 83 21 4341 4344 Bibcode 1999PhRvL 83 4341S doi 10 1103 PhysRevLett 83 4341 Stillinger Frank H Lubachevsky Boris D 1995 Patterns of broken symmetry in the impurity perturbed rigid disk crystal Journal of Statistical Physics 78 3 4 1011 1026 Bibcode 1995JSP 78 1011S doi 10 1007 BF02183698 S2CID 55943037 Further reading editHagen Kleinert Gauge Fields in Condensed Matter Vol II Stresses and defects pp 743 1456 World Scientific Singapore 1989 Paperback ISBN 9971 5 0210 0 Hermann Schmalzried Solid State Reactions Verlag Chemie Weinheim 1981 ISBN 3 527 25872 8 Retrieved from https en wikipedia org w index php title Crystallographic defect amp oldid 1180259886, wikipedia, wiki, book, books, library,

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