Difference between revisions of "Superspace point group"
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Both <math>\Gamma_E^*(K)</math> and <math>\Gamma_I^*(K)</math> are integral representations of ''K'', | Both <math>\Gamma_E^*(K)</math> and <math>\Gamma_I^*(K)</math> are integral representations of ''K'', | ||
as are their conjugates <math>\Gamma_E(K)</math> and <math>\Gamma_I(K)</math>. | as are their conjugates <math>\Gamma_E(K)</math> and <math>\Gamma_I(K)</math>. | ||
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| + | Points in direct space, with lattice coordinates <math>x_1,\dots,x_n</math> transform according to | ||
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| + | [[Image:EmbIncDir.gif]] | ||
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| + | In direct space the internal space <math>V_I</math> is left invariant, and this subspace contains a ''d''-dimensional lattice, that is left invariant. | ||
Revision as of 10:10, 19 May 2009
Groupe ponctuel de superespace (Fr.)
Definition
An (m+d)-dimensional superspace group is a space group with a point group K that leaves an m-dimensional subspace invariant. Therefore, K is R-reducible and its elements are pairs ([math]R_E,~R_I[/math]) of orthogobal transformations. Both [math]R_E[/math] and [math]R_I[/math] may themselves be R-reducible in turn. They form the m-dimensional point group [math]K_E[/math], and the d-dimensional point group [math]K_I[/math], respectively.
Comments
On a lattice basis the point group elements are represented by integral matrices [math]\Gamma (R)[/math]. The action of the point group on the reciprocal lattice is given by the integral matrix [math]\Gamma^*(R)[/math], which is the inverse transpose of [math]\Gamma (R)[/math].
The diffraction spots of an aperiodic crystal belong to a vector module [math]M^*[/math] that is the projection of the n-dimensional reciprocal lattice [math]\Sigma^*[/math] on the physical space. The projections of the basis vectors [math]a_{si}^*[/math] of [math]\Sigma^*[/math] are the basis vectors [math]a_{si}^*[/math] of the vector module [math]M^*[/math]. Therefore, the action of the n-dimensional point group of the superspace group on the basis of [math]M^*[/math] is
[math]R_E a_i^* ~=~ \sum_{j=1}^n \Gamma^*(R)_{ij} a_j^* ,~~(i=1,\dots,n).[/math]
For an incommensurate modulated structure, the submodule of the main reflections is invariant. As a consequence, the elements of the point group in superspace in this case is Z-reducible. There is a basis
such that the point group elements are represented by the integral matrices
Both [math]\Gamma_E^*(K)[/math] and [math]\Gamma_I^*(K)[/math] are integral representations of K, as are their conjugates [math]\Gamma_E(K)[/math] and [math]\Gamma_I(K)[/math].
Points in direct space, with lattice coordinates [math]x_1,\dots,x_n[/math] transform according to
In direct space the internal space [math]V_I[/math] is left invariant, and this subspace contains a d-dimensional lattice, that is left invariant.