Page 339 - Semiconductor For Micro- and Nanotechnology An Introduction For Engineers
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magnetic 146
2D square lattice 71, 72
chain 68, 69
dispersion relation 67 Monte Carlo 229
method 229
lattice 71, 74 simulation 228
layer 17 technique 230
monopole multiple eigenvalue 103
charge 146
N noninteracting particles 178 normalized
nonlinear scattering 196 wavefunction 111, 112
normal mode 82, 84 notation
normalization 152, 172, 174 Dirac 98
O observable 182 position 99
observable quantity 111 oppositely charged atoms 48
Onsager optical
coefficients 267 branch 71, 285
theory 215 interaction 71
operator 119, 121 ordinary differential equation 220
closed form Hamiltonian 103 orthogonal
curl 145 eigenvector 104
eigenvector 121 oscillator
Hamilton 104, 105, 123 ensemble 85
Hamiltonian 50, 103 oscillator spring
momentum 119, 122 amplitude 118
P parameter trajectory 193
Grüneisen 88 transition rate 196
partial differential equation 102, 220, transmission 117
222, 228, 293 wave-like 97, 117
particle particle current density 198
acceleration 196 particles
creation 107 noninteracting 178
current density 200, 201, 204, 207 number 169
density 193 partition function 179, 180, 184
density balance equation 200 canonical 175
destruction 107 grand canonical 180
distribution 170 photon 183
distribution function 192 Pauli
flux 200 principle 196
-like electron 96 Pauli principle 181
number 200 periodic
number conservation 200 boundary condition 115, 173
phase space 192 permeability 146
pseudo 169 relative 147
quasi 182 permittivity 147
reflection 117 relative 147
reflexivity 117 phase space 172, 193
relaxation 203 particle 192
statistics 84 phase-space 194
336 Semiconductors for Micro and Nanosystem Technology
