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Introduction to Solid State Physics for Materials Engineers. Emil Zolotoyabko
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Название: Introduction to Solid State Physics for Materials Engineers

Автор: Emil Zolotoyabko

Издательство: John Wiley & Sons Limited

Жанр: Физика

Серия:

isbn: 9783527831593

isbn:

СКАЧАТЬ (1.28). Sometimes Eq. (1.28) is called as quasi-momentum (or quasi-wavevector) conservation law in the medium with translational symmetry, which should be used instead of the momentum conservation law in a homogeneous medium. We remind that the latter law means 2πG = k_f − k_i = 0, i.e. k_f = k_i.

Note that each vector of reciprocal lattice, G = hb₁ + kb₂ + lb₃, is perpendicular to a specific crystallographic plane in real space. This statement directly follows from Eq. (1.29), which defines the geometric plane for the ends of certain vectors, r_s, the plane being perpendicular to the vector G (Figure 1.14). Bearing in mind possible wave diffraction when propagating through a periodic medium, it is worth to introduce a set of parallel planes of this type (i.e. those given by Eq. (1.29)), which are separated by the d-spacing

(1.37) d equals StartFraction 1 Over bar bold-italic upper G bar EndFraction equals StartFraction 1 Over bar h bold-italic b bold 1 plus k bold-italic b bold 2 plus l bold-italic b bold 3 bar EndFraction

Schematic illustration of the sketch of a crystal plane, normal to the vector of reciprocal lattice, G, which contains the ends of vectors, rs, satisfying Eq. (1.29).

Figure 1.14 Sketch of a crystal plane, normal to the vector of reciprocal lattice, G, which contains the ends of vectors, r_s, satisfying Eq. (1.29).

Figure 1.15 Graphical interrelation between wavevectors of the incident (k_i) and scattered (k_f) waves and the vector of reciprocal lattice, G.

In fact, using graphical representation of Eq. (1.28) (Figure 1.15) and solving the wavevector triangle, we find (with the aid of Eq. (1.24)) that

(1.38) 2 StartAbsoluteValue bold-italic k EndAbsoluteValue sine upper Theta Subscript upper B Baseline equals StartFraction 4 pi sine upper Theta Subscript upper B Baseline Over lamda EndFraction equals 2 pi StartAbsoluteValue bold-italic upper G EndAbsoluteValue

Substituting Eq. (1.37) into Eq. (1.38), we finally obtain the so-called Bragg law:

(1.39) 2 d sine upper Theta Subscript upper B Baseline equals lamda

which provides the relationship between the possible directions for the diffracted wave propagation (via Bragg angles, Θ_B) and inter-planar spacings (d-spacings), d, in crystals. We stress that if λ > 2d, Bragg diffraction is not possible.

Note that for quasicrystals, the diffraction conditions (like Eq. (1.28)) can be deduced from the quasi-momentum (quasi-wavevector) conservation law in the n-dimensional space (hyperspace, n > 3), in which the vectors of reciprocal lattice, G^qc, are:

(1.40) bold-italic upper G Superscript italic q c Baseline equals sigma-summation Underscript 1 Overscript n Endscripts h Subscript i Baseline bold-italic b Superscript italic q c Baseline Subscript i

In case of icosahedral symmetry, n = 6, and the set of basis vectors has the following form:

(1.41) bold-italic upper G Superscript italic q c Baseline equals upper G 0 sigma-summation Underscript 1 Overscript 6 Endscripts h Subscript i Baseline ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript i

$Schematic illustration of the traces of isoenergetic surfaces in reciprocal space for the incident (ki) and diffracted (kf) waves. The point of degeneracy of quantum states is marked by the letter D.$

Figure 1.16 The traces of isoenergetic surfaces (red curves) in reciprocal space for the incident (k_i) and diffracted (k_f) waves. The point of degeneracy of quantum states is marked by the letter D.

where G₀ is some constant and ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript i are unit vectors expressed via the golden ratio (Eq. (1.6)), as:

ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript 1 Baseline equals StartFraction 1 Over 1 plus tau squared EndFraction left-parenthesis 1 comma tau comma 0 right-parenthesis

ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript 2 Baseline equals StartFraction 1 Over 1 plus tau squared EndFraction left-parenthesis tau comma 0 comma 1 right-parenthesis

ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript 3 Baseline equals StartFraction 1 Over 1 plus tau squared EndFraction left-parenthesis tau comma 0 comma negative 1 right-parenthesis

ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript 4 Baseline equals StartFraction 1 Over 1 plus tau squared EndFraction left-parenthesis 0 comma 1 comma negative tau right-parenthesis

ModifyingAbove bold-italic b With Ì‚ Superscript italic q c Baseline Subscript 5 Baseline equals StartFraction 1 Over 1 plus tau squared EndFraction left-parenthesis negative 1 comma tau comma 0 right-parenthesis

(1.42)СКАЧАТЬ

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Introduction to Solid State Physics for Materials Engineers. Emil Zolotoyabko
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