Introduction to solid state physics |
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Page 288
ne2rExB/m nee (SI) RH= - -L . tie This is negative for free electrons, for e is
positive by definition. The lower the carrier concentration, the greater the
magnitude of the Hall constant. Measuring RH is a way of measuring the carrier
concentration.
ne2rExB/m nee (SI) RH= - -L . tie This is negative for free electrons, for e is
positive by definition. The lower the carrier concentration, the greater the
magnitude of the Hall constant. Measuring RH is a way of measuring the carrier
concentration.
Page 331
The effective mass of a hole is defined from an equation of the same form, but for
a positive charge: mh d\h/dt = eE. We have seen from ( 15) that v„ = va, whence
dvjdt = d\h/dt and from a comparison of the equations of motion tnh - -me (20) ...
The effective mass of a hole is defined from an equation of the same form, but for
a positive charge: mh d\h/dt = eE. We have seen from ( 15) that v„ = va, whence
dvjdt = d\h/dt and from a comparison of the equations of motion tnh - -me (20) ...
Page 333
As we proceed in the second band away from the boundary, the amplitude of exp
[i(k — Gi)x] decreases rapidly and m* assumes a small positive value. Here the
increase in electron velocity resulting from a given impulse is larger than that ...
As we proceed in the second band away from the boundary, the amplitude of exp
[i(k — Gi)x] decreases rapidly and m* assumes a small positive value. Here the
increase in electron velocity resulting from a given impulse is larger than that ...
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Contents
CRYSTAL STRUCTURE | 1 |
CRYSTAL DIFFRACTION AND THE RECIPROCAL LATTICE | 43 |
CRYSTAL BINDING | 95 |
Copyright | |
24 other sections not shown
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absolute zero absorption alkali alloy antiferromagnet applied field applied magnetic field atoms axis boundary Brillouin zone calculated Chapter charge components conduction band conduction electrons critical field crystal structure cubic defined density dielectric constant diffraction dipole direction dislocation dispersion relation elastic electric field electron gas energy gap entropy equation equilibrium excited exciton experimental F center Fermi surface ferroelectric ferromagnetic Figure free electron frequency function given heat capacity hole impurity interaction ionic ions lattice constant lattice points low temperatures magnetic field magnon Meissner effect metal momentum motion nearest neighbors neutron normal nuclear nucleus optical orbital paramagnetic particle phase phonon Phys physics plane polarizability polarization positive potential primitive cell quantum reciprocal lattice vector region resonance result room temperature scattering semiconductor shown in Fig solid specimen sphere spin superconducting susceptibility theory thermal tion transition temperature unit vacancies valence band velocity wave wavefunction wavelength wavevector x-ray
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Bibliographic information
| Title | Introduction to solid state physics |
| Author | Charles Kittel |
| Edition | 4, illustrated |
| Publisher | Wiley, 1971 |
| Original from | the University of Michigan |
| Digitized | 21 Nov 2007 |
| ISBN | 0471490210, 9780471490210 |
| Length | 766 pages |
| Subjects | › › Matter Science / Physics / Condensed Matter Solid-state physics Solids |
| Export Citation | BiBTeX EndNote RefMan |