Physical Properties of Crystals: Their Representation by Tensors and Matrices |
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Page 236
... refractive index n for that wave . The refractive indices of the two waves , as functions of the direction of their common wave normal , are obtained by drawing an ellipsoid known as the indicatrix . B X3 -X2 FIG . 13.1 . The indicatrix ...
... refractive index n for that wave . The refractive indices of the two waves , as functions of the direction of their common wave normal , are obtained by drawing an ellipsoid known as the indicatrix . B X3 -X2 FIG . 13.1 . The indicatrix ...
Page 237
... refractive indices n , and n1 , with D parallel to x and x1 X1 respectively . A similar statement applies to the wave normal x3 . For this reason n1 , ng , ng are called the principal refractive indices . Note that refractive index ...
... refractive indices n , and n1 , with D parallel to x and x1 X1 respectively . A similar statement applies to the wave normal x3 . For this reason n1 , ng , ng are called the principal refractive indices . Note that refractive index ...
Page 242
... refractive index of a crystal produced by an electric field is known as the electro - optical effect . A B It has to be remembered that permittivity depends on the frequency of the electric field . Keeping to the special case used above ...
... refractive index of a crystal produced by an electric field is known as the electro - optical effect . A B It has to be remembered that permittivity depends on the frequency of the electric field . Keeping to the special case used above ...
Contents
THE GROUNDWORK OF CRYSTAL PHYSICS | 3 |
3 | 29 |
EQUILIBRIUM PROPERTIES | 51 |
23 other sections not shown
Common terms and phrases
angle anisotropic applied axial B₁ biaxial birefringence centre of symmetry Chapter coefficients components conductivity constant crystal classes crystal properties crystal symmetry cube cubic crystals D₁ defined denoted diad axis dielectric dijk direction cosines displacement electric field ellipsoid equal equation example expression follows forces given grad H₁ H₂ heat flow Hence hexagonal indicatrix isothermal isotropic k₁ magnetic magnitude matrix notation measured moduli monoclinic number of independent Onsager's Principle optic axis optical activity orientation orthorhombic Ox₁ P₁ parallel Peltier permittivity perpendicular photoelastic photoelastic effect piezoelectric effect plane plate polarization positive principal axes produced pyroelectric effect quadric radius vector referred refractive index relation representation quadric represents right-handed rotation S₁ scalar second-rank tensor shear shown strain stress symmetry elements Table temperature gradient thermal expansion thermodynamics thermoelectric effects Thomson heat tion transformation law triclinic trigonal uniaxial values wave normal x₁ zero әт