Page 335 - Semiconductor For Micro- and Nanotechnology An Introduction For Engineers
P. 335
effect
E
photoelectric 162
law 146
energy
effective mass 96, 192 electrostatic
approximation 139 absorption 30, 85
effective mass approximation 139 acoustic 81
eigenfrequency 77 allowable band 134
eigenfunction 103, 114 amplitude 130
momentum 114 atom level 125
eigenmode equation 166 average 84, 174, 175
eigenpair balance equation 200, 209
waveguide 166 band 137
eigenvalue 103, 123 continuous spectrum 106
degeneracy 126 current density 198, 201
degenerate 112 eigenvalue 112, 119
energy 112, 119 ground state 120
equation 74, 103 Helmholtz 87
momentum 112 internal 85, 87, 88
multiple 103 internal store 84
eigenvector kinetic 114
amplitude 74 level 180, 183
operator 121 quantize 163
orthogonal 104 quantized electromagnetic 84
Einstein 144 quantized vibration 84
elastic coefficient range 172
approximation 27 relaxation 201, 203
electric displacement 144 spectrum 104, 111, 184
time-varying 146 total 172
electric field 144 vibrational 82
electrochemical potential 206, 207, zero point 119
209, 210, 212, 214, 215, ensemble 169, 172
253 canonical 170, 174, 176, 177
electrodynamics 143, 154 grand canonical 170, 176
electromagnetic wave 183 microcanonical 170, 171, 176
electron 96, 115 oscillators 85
average position 99 entropy 84, 87
free 96, 108, 115, 116 equation
free wavefunction 114 balance 191, 201, 203, 220
momentum 98 Boltzmann transport 192, 227,
nature of 95 231, 239, 240, 275
particle-like 96 charge relaxation 153
quantum nature 96 constitutive 146, 191
quasi-particle 182 continuity 200, 201
state of free 108 coupled 201
transport 191 density balance 220
unbound 108 diffusion 153
wave 98 drift-diffusion 192, 222, 310
wavefunction 123, 245 eigenmode 166
wave-like 96 energy balance 200, 209
electronic system 192 global balance 192, 220
electro-quasi-statics 154 Helmholtz 147
332 Semiconductors for Micro and Nanosystem Technology