Introduction to Solid State Physics |
From inside the book
Results 1-3 of 81
Page 93
... atoms . ( d ) Figure 38 shows the electron diffraction pattern in the backward direction , from the nickel atoms on the ( 110 ) surface of a nickel crystal . Explain the orientation of the diffraction pattern in relation to the atomic ...
... atoms . ( d ) Figure 38 shows the electron diffraction pattern in the backward direction , from the nickel atoms on the ( 110 ) surface of a nickel crystal . Explain the orientation of the diffraction pattern in relation to the atomic ...
Page 105
... atoms in a crystal . A more important contribution to the repulsion may arise from the overlap of the electron distri- butions of two atoms close to each other . As the two atoms are brought together their charge distributions gradually ...
... atoms in a crystal . A more important contribution to the repulsion may arise from the overlap of the electron distri- butions of two atoms close to each other . As the two atoms are brought together their charge distributions gradually ...
Page 714
... atoms and watch the changes in the levels as the charge distributions of adjacent atoms overlap when the atoms are brought together to form the metal . We can understand the origin of the splitting of free atom energy levels into bands as ...
... atoms and watch the changes in the levels as the charge distributions of adjacent atoms overlap when the atoms are brought together to form the metal . We can understand the origin of the splitting of free atom energy levels into bands as ...
Contents
CRYSTAL STRUCTURE | 1 |
CRYSTAL DIFFRACTION AND THE RECIPROCAL LATTICE | 43 |
CRYSTAL BINDING | 95 |
Copyright | |
22 other sections not shown
Common terms and phrases
absolute zero absorption alkali halide alloy antiferromagnet applied field atoms axis boundary Brillouin zone calculated Chapter charge components conduction band conduction electrons crystal structure cubic density dielectric constant dielectric function diffraction dipole direction dislocation dispersion relation effective mass elastic electric field electron concentration electron gas energy gap equation equilibrium excited exciton experimental F center Fermi surface ferroelectric ferromagnetic Figure free electron frequency function given heat capacity hole impurity interaction ionic lattice constant lattice points low temperatures magnetic field magnetic moment magnon metal modes momentum motion nearest neighbors neutron normal nuclear optical orbital paramagnetic particle phase phonon Phys plane polarization positive potential primitive cell quantum reciprocal lattice vector region resonance result room temperature scattering semiconductor shown in Fig space specimen sphere superconducting theory thermal tion transition unit vacancy valence band velocity wavefunction wavelength wavevector x-ray