## Physical Properties of Crystals |

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Page 83

A force will be transmitted across each face of the

outside the

each face may be resolved into three components. Consider first the three faces ...

A force will be transmitted across each face of the

**cube**, exerted by the materialoutside the

**cube**upon the material inside the**cube**. The force transmitted acrosseach face may be resolved into three components. Consider first the three faces ...

Page 136

The energy of a strained crystal Consider a crystal which in the unstrained state

has the form of a unit

strain with components et. Now let the strain components all be changed to ...

The energy of a strained crystal Consider a crystal which in the unstrained state

has the form of a unit

**cube**, and suppose it is subjected to a small homogeneousstrain with components et. Now let the strain components all be changed to ...

Page 145

This quantity is zero for the directions of the

maximum value of $ in the K111) directions. Hence, if (811–812–4844) is positive

(as it is for all cubic metals except molybdenum), Young's Modulus is a maximum

in the ...

This quantity is zero for the directions of the

**cube**axes (100) and has itsmaximum value of $ in the K111) directions. Hence, if (811–812–4844) is positive

(as it is for all cubic metals except molybdenum), Young's Modulus is a maximum

in the ...

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### Contents

THE GROUND WORK OF CRYSTAL PHYSICS | 3 |

Summary | 29 |

EQUILIBRIUM PROPERTIES | 45 |

47 other sections not shown

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### Common terms and phrases

angle anisotropic applied biaxial birefringence centre of symmetry Chapter conductivity constant crystal classes crystal properties crystal symmetry cube cubic crystals defined denoted diad axis dielectric direction cosines displacement elastic compliances electric field electro-optical electro-optical effect ellipsoid equal equation example expression follows forces given gives grad heat flow Hence indicatrix isothermal isotropic magnetic magnitude matrix notation measured moduli Mohr circle monoclinic number of independent Onsager's Principle optic axis optical activity orientation parallel permittivity perpendicular 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 scalar second-rank tensor shear shown shows strain stress symmetry elements Table temperature gradient thermal expansion thermodynamics thermoelectric effects Thomson heat tion transformation law trigonal uniaxial unit volume values wave normal wave surface written zero