Difference between revisions of "Superspace"
From Online Dictionary of Crystallography
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by ''m''. Then a function ρ('''r'''}) is quasi-periodic if its Fourier transform is given by | by ''m''. Then a function ρ('''r'''}) is quasi-periodic if its Fourier transform is given by | ||
| − | <math>\rho( | + | <math>\rho( r)~=~\sum_{ k \in M^*} \hat{\rho}( k \exp (2\pi i k. r ),</math> |
where the ''Fourier module'' ''M''<sup>*</sup> is the set of vectors (Z-module) of the form | where the ''Fourier module'' ''M''<sup>*</sup> is the set of vectors (Z-module) of the form | ||
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The vectors r<sub>s</sub> have two components: '''r''' and '''r'''<sub>''I''</sub>. The relation is written as | The vectors r<sub>s</sub> have two components: '''r''' and '''r'''<sub>''I''</sub>. The relation is written as | ||
| − | <math>r_s~=~( | + | <math>r_s~=~( r,~ r_I)</math> |
In the superspace there is a reciprocal basis '''a'''<sub>si</sub><sup>*</sup> such that '''a'''<sub>i</sub><sup>*</sup> is the projection of '''a'''<sub>si</sub><sup>*</sup> on the subspace ''V''<sub>E</sub>. | In the superspace there is a reciprocal basis '''a'''<sub>si</sub><sup>*</sup> such that '''a'''<sub>i</sub><sup>*</sup> is the projection of '''a'''<sub>si</sub><sup>*</sup> on the subspace ''V''<sub>E</sub>. | ||
Revision as of 18:39, 18 May 2009
Superespace, Hyperespace (Fr.)
Definition
Superspace is a Euclidean vector space with a preferred subspace VE that has the dimension of the physical space, usually three, but two for surfaces, and one for line structures.
Applications
Superspace is used to describe quasi-periodic structures (See aperiodic crystal). We denote the dimension of the physical space by m. Then a function ρ(r}) is quasi-periodic if its Fourier transform is given by
[math]\rho( r)~=~\sum_{ k \in M^*} \hat{\rho}( k \exp (2\pi i k. r ),[/math]
where the Fourier module M* is the set of vectors (Z-module) of the form
[math]{\bf k}~=~\sum_{i=1}^n h_i {\bf a}_i^* , ~~~(h_i~{\rm integers}),[/math]
for a basis ai* with the property that [math]\sum_i h_i{\bf a}_i^*$=0[/math] implies hi=0 (all i) if the indices hi are integers. The number n of basis vectors is the rank of the Fourier module.
The vectors rs have two components: r and rI. The relation is written as
[math]r_s~=~( r,~ r_I)[/math]
In the superspace there is a reciprocal basis asi* such that ai* is the projection of asi* on the subspace VE. The reciprocal lattice Σ in superspace then is projected on the Fourier module M<su>*</sup>. The function ρ(r) then can be embedded as
[math] \rho_s(r_s)~=~\sum_{k_s\in\Sigma^*} \hat{\rho}(\pi k_s={\bf k}) \exp (2\pi i k_s.r_s).[/math]
The function ρ(r) is the restriction of ρs(rs) to the subspace
[math] \rho({\bf r})~=~\rho_s({\bf r},0).[/math]
Because the Fourier components in superspace belong to reciprocal vectors of Σ*, the function
ρs(rs) is lattice periodic. Its direct lattice Σ is the dual of Σ* and its basis
vectors are ais satisfying asi.asj* = δij. Therefore, the symmetry group
of ρs(rs) is a space-group in the n-dimensional superspace, where the dimension n is equal to the rank
of the Fourier module. In the superspace the usual crystallographic notions and techniques may be applied. For point atoms, the function ρs(rs) is concentrated on surfaces
of co-dimension equal to the dimension of the physical space (See Figure).
Figure Caption: An example of the embedding of a one-dimensional modulated chain with two modulation wave vectors. It consists of an array of two-dimensional surfaces, with three-dimensional lattice periodicity. The intersection of the surfaces with the physical space (a line) gives the positions of the modulated structure.