Zel'dovich Ya.B., Raizer Yu.P. — Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 2) :: Электронная библиотека попечительского совета мехмата МГУ

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Zel'dovich Ya.B., Raizer Yu.P. — Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 2)

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Название: Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 2)

Авторы: Zel'dovich Ya.B., Raizer Yu.P.

Аннотация:

The physical and chemical processes occurring in gases at high temperatures are the focus of this outstanding text by two distinguished physicists. They discuss essential physical influences on the dynamics and thermodynamics of continuous media, combining material from such disciplines as gas dynamics, shock-wave theory, thermodynamics and statistical physics, molecular physics, spectroscopy, radiation theory, astrophysics, solid-state physics, and other fields. Originally published in two volumes

Язык:

Рубрика: Физика/

Статус предметного указателя: Готов указатель с номерами страниц

ed2k: ed2k stats

Год издания: 1967

Количество страниц: 478

Добавлена в каталог: 11.10.2005

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Предметный указатель

Recombination, role of energy balance in      580—585
Recombination, role of resonance radiation      585
Red edge      311 312
Reduced functions      788
Reduced functions, equations for      797 798
Reeves, R.R.      364[22] 435
Reflection method      see “Calibrated reflection method”
Reflectivity      118
Refractive index, behind strong shocks      781—784
Refractive index, compressed water      783—784
Refractive index, ice      784
Reif, T.      120 424
Relaxation in plasmas      416—421
Relaxation in shock waves      489 ff.
Relaxation in shock waves, dissociation      498—504
Relaxation in shock waves, ionization      505—515
Relaxation in shock waves, molecular vibrations      494—498
Relaxation in shock waves, plasma      515—526
Relaxation layer      234 468
Relaxation layer with shock waves      489 ff. (see also “Relaxation in shock waves”)
Relaxation processes      349 ff.
Relaxation processes in sound waves      556—564
Relaxation processes, order of      351
Relaxation times      351 548 561 562
Relaxation times for dissociation      363
Relaxation times for equilibrium radiation      130
Relaxation times for photoprocesses      403
Relaxation times in $\mathrm{NO_{2}}$ formation      379 380
Relaxation times in a plasma      421
Relaxation times in NO formation      378
Relaxation times, rotational      353 469 470
Relaxation times, vibrational      356 360—362 550
Relaxation, dissociation      362—368
Relaxation, phase transition      753
Relaxation, rotational      352 353
Relaxation, translational      349
Remote ignition      92
Representatives      788 (see also “Reduced functions”)
Resler, E.L.      213 426
Resonance radiation      507 513
Resonance radiation, diffusion of      581 582 585
Resonant energy transfer      122
Resonant photons      507
Resonant scattering      114
Resonant scattering cross section at line center      114
Rest mass energy of electron      442 882
Restricted equilibrium      120
Reversible reactions      189
Reynolds number      72 811
Riemann invariants      19—21 26
Rink, J.P.      367 438 502 868
Rise, M.H.      685[23] 720[23] 722[23] 876
Romano, F.      476[9] 864
Romanov, V.E.      283[17] 429
Rosen, P.      400[54] 437
Roskos, R.R.      124[12] 424
Rosseland mean free path      152 153
Rosseland mean free path, air      280
Rosseland mean free path, bremsstrahlung      260
Rosseland mean free path, effect of spectral lines on      297 298
Rosseland mean free path, multiply ionized gas      278—281
Rosseland mean free path, singly ionized gas      274 275
Rosseland weighting factor      153
Rostaeni, A.      400[51 52] 437(2) 510[37] 866
Rotating mirror camera      243
Rotation wave speed      743
Rotational energies      181 304
Rotational energies, $\mathrm{H_{2}}$       178 352
Rotational energies, $\mathrm{N_{2}}$       178 352
Rotational energies, $\mathrm{O_{2}}$       178 352
Rotational energies, NO      178
Rotational partition function      181
Rotational quantum number      304
Rotational relaxation      352 353
Rotational relaxation and bulk viscosity      469 470
Rotational relaxation times      353 469 470
Rotational structure of band spectra      308—312
Roth, W.      362[60] 438 498[61] 868
Roy, M.      476[12] 865
Roze, A.V.      86 422
Rozhdestvenskii, I.B.      188[5] 191[5] 213 425 426
Ryabinin, Yu.N.      234 428
Rydberg      293 442 882
Ryutov, D.D.      343[76] 433
Ryzhov, O.S.      670 874
Sabol, A.P.      213 426
Sachs, R.G.      213 426
Sadovnikov, P.Ya.      374 375[39] 377[39] 378[39] 436 571 571[14] 871
Sadovskii, M.A.      101 423
Saha equation      194 195 444 884
Sakurai, A.      476 813 817[9] 865 879
Salpeter, E.E.      266[5] 289 296[5] 299[5] 428
Samuilov, E.V.      188[5] 191[5] 425
Saturated vapor      586
Savic, P.      344 434
Savin, F.A.      353 362[4] 367[4] 434
Sawtooth absorption curve      273 274
Sayasov, Yu.S.      504[71] 868
Sazykin, A.      484 865
Scabbing      720—722
Scabbing from rarefaction shocks colliding      761 762
Scale height      849
Scale transformation      786 787
Scattering      110 114 115 286
Scattering coefficient      110
Scattering coefficient, mass      111
Scattering cross section      113 115
Schein, M.      605[10] 873
Schirmer, H.      200[10] 276[12] 429
Schlieren photography      244
Schneider, E.G.      604 872
Schott, G.      365[25] 368[25] 436 502[30] 866
Schumann — Runge band system      305 323 330 333 334
Schwartz, R.N.      356[13] 360 435(2)
Schwarzschild approximation      see “Forward-reverse approximation”
Screening effect      251
Screening radius in a plasma      418
Seaton, M.J.      200[10] 276 389[47] 425 429 437
Second law of thermodynamics      4 552
Second positive band system of $\mathrm{N_{2}}$       305 307—310 312 330 334
Second type of self-similar motion      794
Second viscosity coefficient      73 74 76 469 564
Second viscosity coefficient and internal degrees of freedom      74 469
Second viscosity coefficient from rotational relaxation      469 470
Sedov, L.I.      93 95 99 104 422(2) 617 618[13] 618 791 793 794 873 878
Selection rules, diatomic molecules      308
Selective absorption      114
Self-absorption      136
Self-consistent electric field      223 224
Self-similar compression wave, impossibility of continuous solution for      43 44
Self-similar motion      39 785—863 “Sudden
Self-similar motion as asymptotic limit      679—681 792 809 834—839
Self-similar motion of first type      792 793
Self-similar motion of second type      794
Self-similar motion with impulsive load      820—846
Self-similar motion with power-law density      812—817
Self-similar motion, adiabatic integral for      800
Self-similar motion, centered rarefaction wave      38—41 761
Self-similar motion, centered simple wave      see “Centered rarefaction wave”
Self-similar motion, conditions for      790—792
Self-similar motion, dimensional parameters in      791—794
Self-similar motion, energy conservation      824—827
Self-similar motion, exponential      789
Self-similar motion, exponentially decreasing density      859—863
Self-similar motion, exponentially increasing density      852—859
Self-similar motion, infinite energy paradox      826 834—839
Self-similar motion, Lagrangian coordinate      827 828 855
Self-similar motion, limitations on similarity exponent      833 834 840—842
Self-similar motion, momentum conservation      824—827
Self-similar motion, plane arbitrary discontinuities      86 87

Self-similar motion, power-law      789
Self-similar motion, rarefaction wave      33—38 791
Self-similar motion, single differential equation for      799 800
Self-similar motion, singular point condition for      801
Self-similar motion, thermal wave      664—676
Self-similar motion, unloading      761—763
Selivanov, V.V.      187[4] 196 197[4] 206 212 424
Semenov, N.N.      375
Semenov, S.S. (ed.)      234[4] 238[4] 239[4] 243[4] 427
Sen, H.K.      525[45] 867
Senatskii, Yu.V.      338[72] 433
Shadow photography      244
Shafranov, V.D.      515 522 522[43] 867
Shapiro, G.S.      744 876
Shear modulus of elasticity      735 736 742
Shear strain      735
Shear stress      732
Shear stress, critical      740
Shear wave speed      743
Shekhter, B.I.      711 722 876
Sherman, A.      515[84] 869
Sherman, F.S.      487 865
Shklovskii, I.S.      817
Shlyapintokh, I.Ya.      187[4] 196 197[4] 206 212 424
Shnirman, G.L.      686 875(3)
Shock adiabatics      see “Hugoniot curves”
Shock front structure      54 69 75—77 465—546
Shock front structure in a plasma      515—526
Shock front structure in a polarized plasma      524—526
Shock front structure with binary diffusion      485—489
Shock front structure with Burnett approximation      476
Shock front structure with diffusion only      488 489
Shock front structure with dissociation      498—504
Shock front structure with heat conduction only      477—481
Shock front structure with ionization      505—515
Shock front structure with kinetic theory      476
Shock front structure with radiation      526—546 (see also “Radiation in shock waves”)
Shock front structure with relaxation      489 ff. (see also “Relaxation in shock waves”)
Shock front structure with vibrational relaxation      494—498
Shock front structure with viscosity only      481—482
Shock front structure, viscous      468—477
Shock front thickness      73 467 468 471 474—476 489
Shock front thickness in $\mathrm{N_{2}}$ with vibrational relaxation      498
Shock front thickness in $\mathrm{O_{2}}$ with vibrational relaxation      498
Shock front thickness with binary diffusion      486
Shock front thickness, measurement of      244
Shock tubes      88 89 233—245
Shock tubes with combustion      238
Shock tubes, conditions behind reflected wave      238 239
Shock tubes, driver gas      234 235
Shock tubes, methods of measurement      243—245
Shock tubes, principle of operation      234—236
Shock tubes, test gas      234 235
Shock wave front      491 (see also “Relaxation layer with shock waves”)
Shock wave reflection from end of shock tube      89 238 239
Shock wave relations      45—49 471
Shock wave structure      see “Shock front structure”
Shock waves in a plasma      515—526
Shock waves in air      502—505
Shock waves in lead      708
Shock waves in porous materials      712—716
Shock waves in solids      685 ff.
Shock waves in solids, electrical conductivity behind      778—781
Shock waves in solids, experimental determination of temperature and entropy      770—773
Shock waves in solids, Hugoniot curves      705 ff.
Shock waves in solids, linear velocity approximation      710
Shock waves in solids, refractive index behind      781—784
Shock waves in solids, weak      710
Shock waves with anomalous thermodynamic properties      67—69
Shock waves with electric fields      522—526
Shock waves with radiation      see “Radiation in shock waves”
Shock waves with relaxation      489 ff. (see also “Relaxation in shock waves”)
Shock waves, formation of      23 44
Shock waves, isothermal      480 481
Shock waves, limiting density ratio      see “Limiting density ratio across a shock”
Shock waves, moving downward in atmosphere      852—859
Shock waves, moving upward in atmosphere      859—863
Shock waves, rarefaction      757—762
Shock waves, reflection at free surface      716—722 762—778
Short-duration pulse      821 (see also “Impulsive load”)
Silica, heat of vaporization      845
Silver, degeneracy temperature      701
Similarity exponent for implosion      803
Similarity exponent for impulsive load      825 832—834 842—844
Similarity exponent with power-law density      814
Similarity exponent, exponentially decreasing density      860
Similarity exponent, exponentially increasing density      858
Similarity exponent, limitations on      833 834 840—842
Similarity exponent, singular point condition for      802
Similarity transformations      see “Transformation groups”
Similarity variable      788
Similarity variable, exponential      789
Similarity variable, exponential atmosphere      854
Similarity variable, power-law      789
Similarity variable, strong explosion      793
Similarity variable, thermal wave      665
Simple waves      27—30 32
Sinitsyn, M.V.      685 771 773 781 782[51] 877(2)
Sisco, W.B.      515[82] 869
Slater — Landau formula      730
Slater, J.C.      699 875
Slawsky, Z.I.      356[13] 435
Slightly compressed atom, electron density distribution      228
Smith, P.T.      389[49] 437
Smith, S.J.      269[9] 429
Smolkin, G.E.      686[12] 875
Sobel’man, I.N.      287[54] 292[54] 432
Sobolev, N.N.      276 332[48] 431 432
Sodium chloride, cold pressure      692 731
Sodium, degeneracy temperature      701
Solodchenkova, S.A.      268[85] 434
Soshnikov, V.N.      323[27] 323 430(2)
Sound absorption      74 75 555—564
Sound absorption, coefficient of      74 75
Sound absorption, frequency dependence      558 563
Sound dispersion      75 553—564
Sound intensity      9 (see also “Decibels”)
Sound speed      7 554 691 692 732 741—744
Sound speed, complex      561—563
Sound speed, frozen      554 562
Sound speed, longitudinal      742
Sound speed, measurement of in compressed material      746—750
Sound speed, thin plate      742
Sound speed, thin rod      742
Sound wave propagation with viscosity and heat conduction      74 75
Sound waves      see “Finite amplitude waves”
Sound waves, energy of      12
Sound waves, monochromatic      10
Sound waves, plane      7 8 10
Sound waves, propagation velocity of      8
Sound waves, spherical      13—15
Spalling      720 (see also “Scabbing”)
Spark discharge in air      636—638
Specific heat      177 179
Specific heat of condensed media      695—697
Specific heat ratio, complex      561
Specific heat ratio, diatomic gas, vibrations excited      179
Specific heat ratio, diatomic gas, vibrations frozen      179
Specific heat ratio, effective nonequilibrium      548
Specific heat ratio, equilibrium radiation      117
Specific heat ratio, monatomic gas      179
Specific heat with dissociation      184 186 187
Specific heat with ionization      656
Specific heat, diatomic molecules      183
Specific heat, electronic      702—705
Specific heat, power-law relation      656
Specific heat, rotational      178 554
Specific heat, translational      177 178 554
Specific heat, vibrational      178 183 554
Spectra in nebulae      201

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