Difference between revisions of "Lattices"

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(Lattices)
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[[Image:Bcc03-lattice.png|thumb|right|300px|Example of a [[Lattice:BCC|BCC]] lattice.]]
 
[[Image:Bcc03-lattice.png|thumb|right|300px|Example of a [[Lattice:BCC|BCC]] lattice.]]
  
In x-ray scattering, we frequently study materials which have constituents arranged on a well-defined '''lattice'''. For instance, an atomic crystal has atoms which occupy well-defined sites within a representative [[unit cell]], which then repeats in all three directions throughout space. Nanoparticle superlattices are a nanoscale analogue, where each lattice site is occupied by a nanoparticle. Other kinds of nanostructures systems can be considered similarly. Block-copolymers mesophases can be thought of as nanostructures sitting on lattice sites (e.g. cylinders in a hexagonal lattice).
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In x-ray scattering, we frequently study materials which have constituents arranged on a well-defined '''lattice'''. For instance, an atomic crystal has atoms which occupy well-defined sites within a representative [[unit cell]], which then repeats in all three directions throughout space. Nanoparticle [[superlattices]] are a nanoscale analogue, where each lattice site is occupied by a nanoparticle. Other kinds of nanostructures systems can be considered similarly. [[Block-copolymers|Block-copolymer]] mesophases can be thought of as nanostructures sitting on lattice sites (e.g. cylinders in a hexagonal lattice).
  
Well-define realspace lattices (repeating structures) [[Fourier transform|give rise]] to well-defined peaks in [[reciprocal-space]], which makes it possible to determine the realspace lattice by considering the arrangement (symmetry) of the scattering peaks.  
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Well-defined [[realspace]] lattices (repeating structures) [[Fourier transform|give rise]] to well-defined peaks in [[reciprocal-space]], which makes it possible to determine the realspace lattice by considering the arrangement (symmetry) of the [[scattering]] peaks.  
  
 
==Notation==
 
==Notation==
* '''Real space''':
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* '''[[Real space]]''':
 
** Crystal ''planes'':
 
** Crystal ''planes'':
 
*** (hkl) denotes a plane of the crystal structure (and repetitions of that plane, with the given spacing). In cubic systems (but not others), the normal to the plane is [hkl]
 
*** (hkl) denotes a plane of the crystal structure (and repetitions of that plane, with the given spacing). In cubic systems (but not others), the normal to the plane is [hkl]
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==Lattices==
 
==Lattices==
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[[Image:Sc01.png|thumb|right|300px|Example of an alternating simple cubic (NaCl) lattice.]]
 
===Cubic===
 
===Cubic===
 
There are three [http://en.wikipedia.org/wiki/Cubic_crystal_system cubic] space groups:
 
There are three [http://en.wikipedia.org/wiki/Cubic_crystal_system cubic] space groups:
 
* [[Lattice:Simple_cubic|Simple cubic (SC)]]
 
* [[Lattice:Simple_cubic|Simple cubic (SC)]]
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** [[Lattice:Simple_cubic#Alternating_Simple_Cubic|Alternating simple cubic (NaCl)]]
 
* [[Lattice:BCC|Body-centered cubic (BCC)]]
 
* [[Lattice:BCC|Body-centered cubic (BCC)]]
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** [[Lattice:BCC#Body-centered_Two-particle|CsCl]]
 
* [[Lattice:FCC|Face-centered cubic (FCC)]]
 
* [[Lattice:FCC|Face-centered cubic (FCC)]]
There are other lattices that have cubic symmetry:
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There are many conceptually distinct lattices that exhibit one of the above cubic symmetries:
* [[Lattice:Diamond|Diamond lattice (FCC)]]
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* [[Lattice:Diamond|Diamond lattice]] (FCC)
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** [[Lattice:NaTl|B32 (NaTl)]]
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===Hexagonal===
 
===Hexagonal===
 
* [[Lattice:Hexagonal|Hexagonal]]
 
* [[Lattice:Hexagonal|Hexagonal]]
 
** [[Lattice:HCP|Hexagonal close-packed (HCP)]]
 
** [[Lattice:HCP|Hexagonal close-packed (HCP)]]
 
** [[Lattice:Hexagonal diamond|Hexagonal diamond]]
 
** [[Lattice:Hexagonal diamond|Hexagonal diamond]]
** [[Lattice:Wurtzite]]
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*** [[Lattice:Wurtzite|Wurtzite]]
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** [[Lattice:AlB2|AlB<sub>2</sub>]]
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==Symmetry and Space Groups==
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* U. Shmueli, S. R. Hall and R. W. Grosse-Kunstleve, [http://www.springerlink.com/content/p64698026200453u/ Symmetry in reciprocal space] International Tables for Crystallography Volume B: Reciprocal space, 1, Springer 2001 pp 99-161 ISSN 1574-8707 ISBN 978-0-7923-6592-1 (Print) 978-1-4020-5407-5 (Online) [http://dx.doi.org/10.1107/97809553602060000552 doi 10.1107/97809553602060000552]
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==Peak Positions==
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===Cubic===
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:<math>\frac{1}{d_{hkl}^2} = \frac{h^2 + k^2 + l^2}{a^2} </math>
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:<math>q_{hkl} = 2 \pi \left( \frac{h^2 + k^2 + l^2}{a^2} \right)^{1/2}</math>
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===Hexagonal===
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: <math>\frac{1}{d_{hkl}^2} = \frac{4}{3} \left( \frac{h^2 + hk + k^2}{a^2} \right) + \frac{l^2}{c^2} </math>
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: <math>q_{hkl}=2\pi\left( \frac{4(h^2 + hk + k^2)}{3a^2} + \frac{l^2}{c^2} \right)^{1/2}</math>
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===Tetragonal===
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: <math>\frac{1}{d_{hkl}^2} = \frac{h^2 + k^2}{a^2} + \frac{l^2}{c^2} </math>
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: <math>q_{hkl} = 2\pi \left ( \frac{h^2 + k^2}{a^2} + \frac{l^2}{c^2} \right )^{1/2} </math>
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===Orthorhombic===
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: <math>\frac{1}{d_{hkl}^2} = \frac{h^2}{a^2} + \frac{k^2}{b^2} + \frac{l^2}{c^2} </math>
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: <math>q_{hkl}^2 = 2\pi \left ( \frac{h^2}{a^2} + \frac{k^2}{b^2} + \frac{l^2}{c^2} \right )^{1/2} </math>
  
 
==See Also==
 
==See Also==
 
* [http://en.wikipedia.org/wiki/Crystal_structure Wikipedia: Crystal Structure]
 
* [http://en.wikipedia.org/wiki/Crystal_structure Wikipedia: Crystal Structure]
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* [[Unit cell]]
 
* [[Lattice:Packing fraction]]
 
* [[Lattice:Packing fraction]]
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* [[Lattices of nano-objects]]
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* [http://www.cryst.ehu.es/html/cryst/magnext.php?from=magnext&magtr=9 Space Group List]
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* M. Nespolo, M. I. Aroyo and B. Souvignier [http://scripts.iucr.org/cgi-bin/paper_yard?in5013 Crystallographic shelves: space-group hierarchy explained] ''J. Appl. Cryst.'' '''2018''' [https://doi.org/10.1107/S1600576718012724 doi: 10.1107/S1600576718012724]
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* M. Nespolo [http://scripts.iucr.org/cgi-bin/paper?to5189 Lattice versus structure, dimensionality versus periodicity: a crystallographic Babel?] ''J. Appl. Cryst.'' '''2019''', 52. [https://doi.org/10.1107/S1600576719000463 doi: 10.1107/S1600576719000463]

Latest revision as of 10:27, 19 February 2019

Example of a BCC lattice.

In x-ray scattering, we frequently study materials which have constituents arranged on a well-defined lattice. For instance, an atomic crystal has atoms which occupy well-defined sites within a representative unit cell, which then repeats in all three directions throughout space. Nanoparticle superlattices are a nanoscale analogue, where each lattice site is occupied by a nanoparticle. Other kinds of nanostructures systems can be considered similarly. Block-copolymer mesophases can be thought of as nanostructures sitting on lattice sites (e.g. cylinders in a hexagonal lattice).

Well-defined realspace lattices (repeating structures) give rise to well-defined peaks in reciprocal-space, which makes it possible to determine the realspace lattice by considering the arrangement (symmetry) of the scattering peaks.

Notation

  • Real space:
    • Crystal planes:
      • (hkl) denotes a plane of the crystal structure (and repetitions of that plane, with the given spacing). In cubic systems (but not others), the normal to the plane is [hkl]
      • {hkl} denotes the set of all planes that are equivalent to (hkl) by the symmetry of the lattice
    • Crystal directions:
      • [hkl] denotes a direction of a vector (in the basis of the direct lattice vectors)
      • denotes the set of all directions that are equivalent to [hkl] by symmetry (e.g. in cubic system 〈100〉 means [100], [010], [001], [-100], [0-10], [00-1])
    • hkl denotes a diffracting plane
  • Reciprocal space:
    • Reciprocal planes:
      • [hkl] denotes a plane
      • denotes the set of all planes that are equivalent to [hkl]
    • Reciprocal directions:
      • (hkl) denotes a particular direction (normal to plane (hkl) in real space)
      • {hkl} denotes the set of all directions that are equivalent to (hkl)
    • hkl denotes an indexed reflection

Lattices

Example of an alternating simple cubic (NaCl) lattice.

Cubic

There are three cubic space groups:

There are many conceptually distinct lattices that exhibit one of the above cubic symmetries:

Hexagonal

Symmetry and Space Groups

Peak Positions

Cubic

Hexagonal

Tetragonal

Orthorhombic

See Also