Introduction to Solid State Physicsproblems after each chapter |
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Page 139
where Q is the flux of thermal energy ( energy transmitted across unit area per
unit time ) ; K is often expressed in units cal / cm - sec - deg or watts / cm - deg .
To convert to watts / cm - deg , multiply K in cal / cmsec - deg by 4.186 . The form
of ...
where Q is the flux of thermal energy ( energy transmitted across unit area per
unit time ) ; K is often expressed in units cal / cm - sec - deg or watts / cm - deg .
To convert to watts / cm - deg , multiply K in cal / cmsec - deg by 4.186 . The form
of ...
Page 150
Berman24 has measured the thermal conductivity of three alloys ( German silver ,
stainless steel , and constantan ) between 2 ° and 90 ° K and found electron and
phonon contributions of equal orders of magnitude . The total thermal resistivity ...
Berman24 has measured the thermal conductivity of three alloys ( German silver ,
stainless steel , and constantan ) between 2 ° and 90 ° K and found electron and
phonon contributions of equal orders of magnitude . The total thermal resistivity ...
Page 151
1000 800 Iron alloys 600 400 Mild 0.1 % C 2 % Ni 200 3 % Ni 2 % Mn 13 % Cr -4
% AI 13 % Mn Thermal conductivity ( milliwatts / cm deg K ) 100 57 % Ni 80 60 39
% Mn -13 % Cr , quenched 19 % Cr 40 or 13 % Mn , 1 % Cr 24 % Ni31 % Ni ...
1000 800 Iron alloys 600 400 Mild 0.1 % C 2 % Ni 200 3 % Ni 2 % Mn 13 % Cr -4
% AI 13 % Mn Thermal conductivity ( milliwatts / cm deg K ) 100 57 % Ni 80 60 39
% Mn -13 % Cr , quenched 19 % Cr 40 or 13 % Mn , 1 % Cr 24 % Ni31 % Ni ...
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Contents
DIFFRACTION OF XRAYS BY CRYSTALS | 44 |
CLASSIFICATION OF SOLIDS LATTICE ENERGY | 63 |
ELASTIC CONSTANTS OF CRYSTALS | 85 |
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alloys applied approximately associated atoms axis band boundary calculated cell chapter charge concentration condition conductivity consider constant crystal cubic density dependence determined dielectric diffusion direction discussion dislocation distribution domain effect elastic electric electron elements energy equal equation equilibrium experimental expression factor field force frequency function germanium give given heat capacity hexagonal holes important impurity increase interaction ionic ions lattice levels London magnetic magnetic field mass material measurements metals method motion normal observed obtained parallel particles Phys physics plane polarization positive possible potential problem properties range reference reflection region relation resistivity result room temperature rotation shown in Fig simple solid solution space space group specimen structure surface symmetry Table temperature theory thermal tion transition unit usually values vector volume wave zero zone