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| Ïîèñê ïî óêàçàòåëÿì |
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| Ashcroft N.W., Mermin N.D. — Solid State Physics |
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| Ïðåäìåòíûé óêàçàòåëü |
Screening current 734
Screening in p-n junction 611
Screening of Hartree — Fock approximation 344 519—521
Screening of ion-ion interaction 513
Screening, Lindhard 343—344
Screening, overscreening 519
Screening, overscreening, and superconductivity 739—740
Screening, screened Coulomb potential 342
Screening, screened Coulomb potential, oscillations in 343
Screening, Thomas — Fermi 340—342
Screw axis 114n 126
Screw dislocation 632 see
Second sound 506—508
Seebeck effect 24 256
Seebeck effect, lack of in superconductors 256 730 751n
Self-consistent field (Hartree) approximation see "Periodic potential"
Semiclassical model 214—241 see "Orbits"
Semiclassical model and carrier types 218—219
Semiclassical model and excitons 628
Semiclassical model and filled bands 221—223
Semiclassical model and Hall effect 234—236
Semiclassical model and holes 225—229
Semiclassical model and impurity levels in semiconductors 577—580
Semiclassical model and inhomogeneous semiconductors 591—592
Semiclassical model and inhomogeneous semiconductors, possibility of failure 592
Semiclassical model and magnetoresistance 234—239 240 241
Semiclassical model and motion in crossed fields 233
Semiclassical model and orbit quantization 269 271—272
Semiclassical model and thermal conductivity 253—256
Semiclassical model and thermoelectric effects 257—258
Semiclassical model in static electric field 224 241
Semiclassical model in uniform magnetic field 229—233
Semiclassical model vs. free electron model 214
Semiclassical model, AC electrical conductivity 252 253
Semiclassical model, DC electrical conductivity 250—251
Semiclassical model, DC electrical conductivity, in uniform magnetic field 259 261—262
Semiclassical model, equations of motion 216
Semiclassical model, Hamiltonian formulation 771
Semiclassical model, limits of validity 219—221 252 773—775 779
Semiclassical model, Liouville's theorem 222 771
Semiclassical model, phase space 221
Semiclassical model, transport theory 244—262
Semiconductors 562—613
Semiconductors vs. insulators 562
Semiconductors vs. semimetals 304n
Semiconductors, band structure, examples of 568—572
Semiconductors, band structure, germanium 569—570
Semiconductors, band structure, indium antimonide 570
Semiconductors, band structure, silicon 569
Semiconductors, carrier densities 572—577 581—584 586—587 see
Semiconductors, chemical potential 573 575—577
Semiconductors, chemical potential vs. Fermi energy 142n 573n
Semiconductors, conduction bands 562
Semiconductors, conductivity 563—565
Semiconductors, cyclotron resonance 570—572
Semiconductors, degenerate 573
Semiconductors, density of levels 562 574 586
Semiconductors, density of levels, with impurities 579
Semiconductors, diamagnetism (doped) 666
Semiconductors, diffusion constant 602
Semiconductors, diffusion length 604—605
Semiconductors, doping of 590—591
Semiconductors, electrochemical potential 593—594
Semiconductors, energy gap (band gap) 562—564
Semiconductors, energy gap (band gap), measurement of 566—568
Semiconductors, energy gap (band gap), table 566
Semiconductors, energy gap (band gap), temperature dependence of 566—567
Semiconductors, examples 564—566
Semiconductors, extrinsic 564
Semiconductors, extrinsic, carrier densities 575—577
Semiconductors, Fermi level 573n
Semiconductors, generation of carriers 603
Semiconductors, impurities see "Impurities in semiconductors"
Semiconductors, intrinsic 564
Semiconductors, intrinsic, carrier densities 572—575
Semiconductors, law of mass action 574
Semiconductors, majority carriers 598
Semiconductors, Minority carriers 595n 598
Semiconductors, mobility 563n 601—602
semiconductors, N-type 577
Semiconductors, nondegenerate 573
Semiconductors, nondegenerate, transport in 585
Semiconductors, optical properties of 566—568
Semiconductors, p-n junction 590 see
semiconductors, P-type 577
Semiconductors, paramagnetism (doped) 666
Semiconductors, photoconductivity 563
Semiconductors, polar 565
Semiconductors, recombination of carriers 603
Semiconductors, recombination time 603
Semiconductors, resistance 562—564
Semiconductors, resistance, graph 565
Semiconductors, semiclassical model 591—592
Semiconductors, thermopower 563
Semiconductors, valence bands 562
Semimetals 304—305
Semimetals vs. semiconductors 304n
Semimetals, effective mass 305n
Semimetals, specific heat 307n
Shear strain 630
Shear stress 631
Shell model (.onic crystals) 425n 546
Shown, it can be 167 277 280 320 322 324 333 343 442 503 664 683 685 707 708 734n 741 782 792 793 794
Shubnikov — de Haas effect 265
Silsbee effect 730
Simple cubic Bravais lattice 65
Simple cubic Bravais lattice, coordination number 71
Simple cubic Bravais lattice, example among elements 69
Simple cubic Bravais lattice, lattice sum of inverse powers 400
Simple cubic Bravais lattice, packing fraction 83
Simple cubic Bravais lattice, reciprocal of 88
Simple hexagonal Bravais lattice 77 see
Simple hexagonal Bravais lattice, reciprocal of 88—89
Simple hexagonal Bravais lattice, relation to orthorhombic 119n
Simple hexagonal Bravais lattice, relation to rhombohedral (trigonal) 125n
Simple metals (nearly free electron metals) 152 306
Simple monoclinic Bravais lattice 118
Simple orthorhombic Bravais lattice 117
Simple tetragonal Bravais lattice 115
Singlet states 675
Singlet-triplet splitting 676—679
Size effects 280—281
Skin depth 277 281
Slacking faults 637—638
Slater approximation to exchange term 337
Slater determinant 333
SLIP 631
Small oscillations approximation 422 488
Sodium chloride structure 80
Sodium chloride structure in alkali halides 390
Sodium chloride structure, compounds with, table of 80
Sodium chloride structure, structure factor 109—110
Soft modes 456n
Soft modes in ferroelectrics 556
Soft X ray emission see "X ray"
Sommerfeld expansion 45—46 53
Sommerfeld expansion, derivation 760—761
Sommerfeld theory of metals 30—55 see
Sound see also "Elasticity theory
Sound and continuum mechanics 514n
Sound as long wavelength limit of lattice vibrations 440
Sound in classical gas 506—507
Sound in metals 513—515
Sound in metals, and superconductivity 736
Sound in metals, attenuation of, and Fermi surface 275—277
Sound, Bohm — Staver relation for velocity in metals 514
Sound, second 506—508
Space charge effects in thermionic emission 363
Space charge region (depletion layer) 591 see
Space groups 112
| Space groups, equivalence of 115n
Space groups, number of 119—120
Space groups, related to point groups and Bravais lattices 125—126
Space groups, symmorphic vs. nonsymmorphic 126
Specific heat (electronic) and density of levels 17
Specific heat (electronic) in superconductors 734—735
Specific heat (electronic) in superconductors, at transition 745
Specific heat (electronic) in superconductors, at transition, measured values of discontinuity 747
Specific heat (electronic) in superconductors, low temperature 746
Specific heat (electronic) in superconductors, relation to critical field 754
Specific heat (electronic), compared with lattice 463—464 530
Specific heat (electronic), constant volume vs. constant pressure 49n
Specific heat (electronic), cubic term 54 59 530
Specific heat (electronic), failure of classical theory 22—23
Specific heat (electronic), free electron theory 43 46—49
Specific heat (electronic), free electron theory, table 48
Specific heat (electronic), linear term 47—48 59
Specific heat (electronic), linear term, phonon collection to 520n
Specific heat (lattice) 417 453—464 see
Specific heat (lattice) for nonlinear (small k) dispersion 468
Specific heat (lattice), compared with electronic 463—464 530
Specific heat (lattice), compared with magnetic 669
Specific heat (lattice), constant volume vs. constant pressure 427n 492
Specific heat (lattice), Debye model 457—461
Specific heat (lattice), Debye model, interpolation formula 459
Specific heat (lattice), Debye model, interpolation formula, graph 460
Specific heat (lattice), Debye model, interpolation formula, table 461
Specific heat (lattice), Einstein model 462—463
Specific heat (lattice), Einstein model, compared with Debye model 462—463
Specific heat (lattice), Einstein model, graph 463
Specific heat (lattice), failure of classical theory 426—429
Specific heat (lattice), general form in harmonic approximation 454
Specific heat (lattice), high temperature form 454—455 467—468
Specific heat (lattice), in d-dimensions 468
Specific heat (lattice), low temperature form 452 455—457
Specific heat, magnetic, compared with lattice 669
Specific heat, singularity at critical point 699
Spectroscopic code 652
Specular reflection 96n
Spheres, close packing of see "Close packing of spheres"
Spin correlation function 706
Spin correlation function, high temperature form 710—711
Spin correlation function, scaling form near critical temperature 714n
Spin density wave 684
Spin entropy 659—661
Spin hamiltonian 679—681 see "Magnetic
Spin Hamiltonian vs. dipolar interaction energy 680
Spin Hamiltonian, isotropy of 680
Spin of electron 35
Spin of electron and density of levels 143n
Spin waves see also "Heisenberg model"
Spin waves, in anisotropic Heisenberg model 708n 773
Spin waves, in antiferromagnets 708
Spin waves, in ferromagnets 704—709
Spin waves, in ferromagnets, and low temperature spontaneous magnetization 707—709
Spin waves, observation of 709
Spin waves, superposition of 706—707
Spin-orbit coupling, and magnetic anisotropy 680 720
Spin-orbit coupling, and magnetic breakthrough 220
Spin-orbit coupling, and magnetic interactions 674
Spin-orbit coupling, in divalent hexagonal metals 299
Spin-orbit coupling, in hexagonal close packed metals 169 299
Spin-orbit coupling, in nearly tree electron calculations 169
Spin-orbit coupling, in tight binding method 186
Spontaneous magnetization 672 694 see "Ferromagnetism"
Spontaneous magnetization, general mean field form 716
Spontaneous magnetization, low temperature form, Heisenberg model 707—709
Spontaneous magnetization, low temperature form, mean field theory 716
Spontaneous magnetization, singularity at critical point 699
State vs. level 32n
Static lattice model 61 416
Statistical mechanics, fundamental rule of 426n
Stefan — Boltzmann law 467
Stoichiometric alloys 309
Stokes component 181
Strain components 445
Strain tensor 144
Strength of crystals see also "Dislocations"
Strength of crystals, perfect 630
Strength of crystals, real 635—636
Strictly longitudinal or transverse modes 442 see
Structure factor 104—107
Structure factor for bcc Bravais lattice, considered as simple cubic with a basis 105
Structure factor for diamond structure 106
Structure factor for hexagonal close-packed structure 109
Structure factor for sodium chloride structure 109—110
Structure factor for zincblende structure 109
Structure factor in divalent hexagonal metals 299
Structure factor in nearly free electron approximation 166—168
Structure factor, dynamical 792
Sublattices, magnetic 695 see "Ferrimagnetism"
Superconductivity 726—755 see Cooper Schrieffer "Cooper "Critical "Energy "Ginzburg "London "Persistent "Tunneling"
Superconductivity and acoustic attenuation 736
Superconductivity and infrared absorption 735—736
Superconductivity and microwave absorption 735
Superconductivity and triplet pairing 741
Superconductivity vs. perfect conductivity 731—738
Superconductivity, coherence length 738n 742
Superconductivity, critical current 730
Superconductivity, critical current, in cylindrical wire 755
Superconductivity, critical temperature 728
Superconductivity, critical temperature, table 729
Superconductivity, density of superconducting electrons 737
Superconductivity, destruction of by applied field 728 see
Superconductivity, elements table of 726
Superconductivity, flux quantization 734n 749
Superconductivity, gapless 727n
Superconductivity, ground state 741
Superconductivity, hard superconductors 734
Superconductivity, intermediate state 733n
Superconductivity, isotope effect 739
Superconductivity, Josephson effects 751—753
Superconductivity, latent heat in magnetic field 754
Superconductivity, magnetization curves 733
Superconductivity, Meissner (Meissner — Ochsenfeld) effect 731—730 746—747
Superconductivity, mixed state 733
Superconductivity, mixed state vs. intermediate state 733n
Superconductivity, order parameter 747
Superconductivity, perfect diamagnetism 727
Superconductivity, phase diagram 732
Superconductivity, specific heat, discontinuity 745 747
Superconductivity, specific heat, low temperature electronic 746
Superconductivity, specific heat, relation to critical field 754
Superconductivity, strong coupling 743 744—745
Superconductivity, thermal conductivity 730—731
Superconductivity, thermodynamics of 753—754
Superconductivity, thermoelectric properties 256 730 751n
Superconductivity, type I vs. type II 732—733
Superconductivity, vortex lines 733—734
Superexchange 681—682
Surface corrections to bulk one-electron potential 354—357
Surface defects 617 637—638 see
Surface dipole layer 358
Surface levels 367—371
Surface levels and Bloch's theorem 368
Surface levels, nearly free electron theory 369—371
Surface plasmons 27
Susceptibility, magnetic 645 see "Curie
Susceptibility, magnetic, alkali halide ions, table for 649
Susceptibility, magnetic, atomic 645—650 653—656
Susceptibility, magnetic, high temperature (Heisenberg model) 709—712
Susceptibility, magnetic, high temperature (Heisenberg model), and calculation of critical temperature 712
Susceptibility, magnetic, Landau diamagnetic 664—665
Susceptibility, magnetic, Larmor diamagnetic 648—650
Susceptibility, magnetic, mean field (Curie — Weiss law) 718
Susceptibility, magnetic, molar 649
Susceptibility, magnetic, noble gas atoms table for 649
Susceptibility, magnetic, of antiferromagnet 699 702
Susceptibility, magnetic, of ions with partially filled shells 653—659
Susceptibility, magnetic, Pauli paramagnetic see "Paramagnetism"
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