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

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СКАЧАТЬ 1.18 Illustration of the simultaneous appearance of several high-order rotation axes in a crystal.

      In fact, it follows from triangle DOB that DB = 2⋅DO⋅sin(δ/2). The plane of triangle DAB is perpendicular to the axis OA and hence the angle ∠ OAD = 90°. If so, DA = DO⋅sinδ and from triangle DAB, the segment DB = 2⋅DA⋅sin(φ/2) = 2⋅DO⋅sin(φ/2)⋅sin δ . Comparing two expressions for segment DB, given in this paragraph, yields sine StartFraction delta Over 2 EndFraction equals sine StartFraction phi Over 2 EndFraction sine delta, or

      For a fourfold rotation axis (4, φ = 90°), Eq. (1.A.2) gives cosStartFraction delta Over 2 EndFraction equals StartFraction 1 Over StartRoot 2 EndRoot EndFraction, i.e. δ = 90°. This is the angle between cube edges. In other words, crystal symmetry permits the existence of single axis 4, or three such axes, arranged as cube edges, i.e. with angles δ = 90° between them. This combination exists in classes 432 and m ModifyingAbove 3 With bar m of the cubic symmetry system (Table 1.1). In cubic class ModifyingAbove 4 With bar 3 m, we find three fourfold roto-inversion axes, which combine 90° rotation followed by inversion operation.

      For a sixfold rotation axis (6, φ = 60°), Eq. (1.A.2) yields cos(δ/2) = 1, i.e. δ = 0. In other words, crystal symmetry allows the existence of single sixfold axis only in all classes of hexagonal symmetry (Table 1.1).

      As was already mentioned, twinning is very interesting and practically important phenomenon in crystal physics, which is tightly related to specific symmetry operations. The phenomenon of twinning in crystals has been extensively studied due to its emergence in crystal growth and phase transformations and its substantial effect on mechanical, electrical, and optical properties in real crystals. In fact, twinning is one of the key mechanisms of plastic deformation in metals and ceramics. Quite often it serves as a structural basis for different types of ferroelectric domains (see Chapter 12) or structural variants in shape-memory alloys.

      In contrast to what we have learned until now, symmetry operations involved into twinning processes are not included into the point group of a particular crystal, in which twinning occurs. Correspondingly, twins are crystal parts (sometimes called individuals), which are transformed into each other under such symmetry operations. In fact, if a specific symmetry element, considered for twinning, belongs to the crystal point group, its application to one crystal part would produce perfect continuation of the crystal, rather than a twin. In principle, every basic symmetry element, introduced earlier in Section 1.1, may serve for twinning, if it does not belong to the point group set for a given crystal. However, most frequently twins are produced by reflection in a mirror plane or by a 180° rotation about the twofold rotation axis perpendicular to the boundary plane between the twinned parts. If a crystal has an inversion center, both operations result in identical twins.

Schematic illustration of the twin formation in monoclinic lattice via mirror reflection in plane containing the b- and c-translations. The latter is perpendicular to the plane of drawing. The a- and b-translation vectors are indicated by red arrows. Twins are crystal parts located at right-hand and left-hand sides from the trace of the twinning plane. Schematic illustration of the twin formation in orthorhombic lattice via mirror reflection in plane containing the (b + a)- and c-translations. The latter is perpendicular to the plane of drawing. The a- and b-translation vectors are indicated by red arrows. Twins are crystal parts located at right-hand and left-hand sides from the trace of twinning plane.