## Introduction to Solid State Physics |

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Page 17

... may serve as a simple introduction to the principles of space groups. X-RAY

DIFFRACTION BY CRYSTALS In order to explore the structure of crystals we

require waves which interact with atoms and which have a

comparable ...

... may serve as a simple introduction to the principles of space groups. X-RAY

DIFFRACTION BY CRYSTALS In order to explore the structure of crystals we

require waves which interact with atoms and which have a

**wavelength**comparable ...

Page 22

As the

glancing angles must be used. ATOMIC SCATTERING FACTOR The intensity of

a given diffracted wave depends on a number of factors. One of these is the

atomic ...

As the

**wavelength**is decreased, the angle is decreased : for gamma-raysglancing angles must be used. ATOMIC SCATTERING FACTOR The intensity of

a given diffracted wave depends on a number of factors. One of these is the

atomic ...

Page 69

maximum is close4 to the

The

maximum is close4 to the

**wavelength**for which the absorption is a maximum.The

**wavelength**at maximum reflection is known as the residual ray or Reststrahl**wavelength**, and the selective reflection has been employed experimentally to ...### What people are saying - Write a review

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### Contents

LATTICE ENERGY OF IONIC CRYSTALS | 29 |

ELASTIC CONSTANTS OF CRYSTALS | 43 |

LATTICE VIBRATIONS | 60 |

Copyright | |

13 other sections not shown

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### Common terms and phrases

alkali alloy antiferromagnetic applied approximation atoms axes axis barium titanate boundary Brillouin zones calculated charge coefficient conduction band consider crystal structure cube cubic crystal Curie point curve Debye density diamagnetic dielectric constant diffraction dipole direction discussed dislocation displacement distribution domain effect elastic electric field entropy equation equilibrium experimental F-centers factor Fermi ferroelectric ferromagnetic free electron frequency heat capacity holes impurity interaction ionic crystals ions lattice constant lattice points London low temperatures magnetic field mean free path metals molecules motion nearest neighbor normal observed orbital parallel paramagnetic particles perovskite phonons Phys physical plane polarizability polarization positive potential Proc quantum ratio region resonance result room temperature rotation scattering Seitz shear Shockley shown in Fig simple cubic single crystal sodium chloride solids specimen spin superconducting susceptibility symmetry theory thermal tion unit cell unit volume valence values vector velocity wave functions wavelength x-ray zero