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Author and subject index volume 43, 1993
PROGRESS IN SURFACE SCIENCE, VOLUME 43 AUTHOR INDEX
Abricossova, I.I. 265 Abrikosova, I.I. 108, 114, 121, 184, 265, 272 Adam, N. 152 Adamson, I. 82 Adlfinger, K.H. 113 Aidanova, O.S. 185 Akimov, Yu.P. 222, 240 Aktaruzzaman, A.F.M. 358 Alder, B.J. 113 Aleinikova, I.N. 350, 351 Alekseev, O.L. 127 Ananyan, A.A. 221, 240 Anderson, D.M. 213 Andreyev, S.V. 185 Annis, B.K. 331 Archard, I.F. 351 Archer, B.J. 337 Arutunian, M.A. 185 Arutyunyan, M.A. 190 Ash, S.G. 121 Avetisyan, R.A. 337 Aylmore, L.A° 337 Babchin, A. 113 Bakanov, S.P. 280, 286, 331, 336, 358 Balaschova, N.A. 105 Bangham, D.M. 185 Baran, A.A. 127 Barer, S.S. 213, 222, 231, 240 Barnes, G.T. 337 Bartenev, G.M. 351 Batova, G.A. 280, 286 Bazaron, U.B. 202 Belouschek, P. 121 Bergmann, P. 17, 81 Bessonov, S. 266 Bierbrauer, E. 272 Biermans, M. 240 Bigg, E.K. 320 Bigg, E.R. 337 Bikerman, J.J. 185 Black, W. 114, 184 Blodgett, K. 26 Bogdanov, O.S. 266 Boiko, Yu.P. 127 Bondi, A. 207
Borisova, V.M. 337 Brandt, G.H. 222, 240 Bressler, S.E. 82 Brock, J.R. 331 Broddhurst, D. 108 Brownscombe, J.L. 320, 337 Bulgadnaev, A.V. 202 Burgers, W. 22, 33 Buz~goh, A. 35 Cary, J.W. 222, 240 casimir, H. 73, 108 casimir, H.B.G. 266 Cassimir, H.B.G. 114 chaimov-Malkov, V.Ya. 213 Chapman, S. 286, 331 Cheng, L. 351 Cheng, ¥.S. 351 Cherneva, E. 272 Cherny, L.T. 350 Cheverev, V.G. 222, 240 chistolinov, L.V. 240 Chmutov 73 Chmutov, R.V. 185 Christotinov, L.V. 222 Churaev, N.V. 113, 114, 121, 127, 190, 207, 213, 221, 222, 231, 239, 240 Cluny, J.S. 113 Cook, D. 358 Corkill, A. 38 Corkill, J.M. ' 113 Cowling, T. 331 Cowling, T.G. 286 Dahneke, B. 351 Davies, D.K. 351 de Jongh, J.G.V. 114, 184 De Vries, A.J. 184 De Vries, D.A. 240 de Vries, D.A. 231 Defay, R. 113 DeGroot, S.P. 336 Deraguin, B.V. 350 Derjaguin, B. 1, 5, 16, 17, 25, 28, 31, 33, 37, 47, 134, 152, 309 Derjaguin, B.V. 13, 73, 81, 82, 104, 105, 108, 113, I
2 (Derjaguin, B.V., cont.) 114, 121, 127, 151, 158, 165, 213, 231, 239, 240, 265, 266, 272, 308, 320, 331, 336, 337, 351, 358 Deryagin (Derjaguin), B.V. 190, 201, 202, 207, 221, 222, 280, 286, 301 Deryaguin (Derjaguin), B.V. 184, 185 Devor, W. 350 Dijkema, K.M. 213, 222, 240 Distler, G.I. 202 Donnan, F. 31 Dostavalov, B.N. 222 Dostovalov, B.N. 240 Dresner, L. 190 Dube, G. 37 Dukhin, S.S. 127, 158, 165, 185, 201, 265, 266, 280, 286 Dumansky, A.V. 127 Dykhne, A.M. 358 Dzyaloshinski, I.U. 121 Dzyaloshinskij, I.E. 114 Dzyaloshinsky, I.E. 113, 158, 165, 201, 266 Eaborn, C. 207 Ebert, K. 114 Efremova, E.N. 184, 185 Eigeles, M.A. 184, 265 Eilers, H. 34, 73, 114 Einstein, A. 286 Ekserova, D. 121, 184 Ellis, R. 31, 55 Epstein, P. 331 Erschler, B. 152 Ershov, A.P. 190 Ershov, E.D. 222, 240 Ershov, V.A. 337 Ershova, G.F. 121, 231 Ershova, I.G. 222, 240 Esmen, N.A. 351 Evans, L.F. 266 Everett, D.H. 113, 121, 222, 240 Ewers, W.E. 266 Exerova, D. 105 Exzerova, D. 113 Facy, L. 286 Fankuchen 28 Fedoseyev, V.A. 320, 337 Fedyakin, N.N. 185, 301 Fergusson, R.R. 331 Fletcher, N.H. 213, 231, 338 Fox, H.W. 207 Frankel, S. 105 Freundlich, H. 32
AUTHOR
INDEX
Friberg, S. 113 Fridrikhsberg, D.A. 201 Frumkin, A. 17, 37, 152 Frumkin, A.D. 184 Frumkin, A.N. 73, 105, 184, 265, 272 Frumkin, N.A. 105 Fuchs, N. 22, 50 Fuchs, N.A. 114, 320, 338 Fuks, G.I. 105, 266 Fuks, N. 266 Futran, M.F. 266 Gaidukov, M.N. 331 Gaudin, A.M. 266 Gel'mukhanov, F.Kh. 358 Gentry, J.W. 337 Gershuny, F.Z. 331 Gheiner, A.V. 358 Gibbs, W. 152 Gillespie, T. 351 Gilpin, R.R. 222, 240 Glaszman, Yu.M. 184 Glazman, Ju.M. 121 Globus, A.M. 222, 240 Gol'danskii, V.I. 207 Goldshtik, M.A. 331 Goldsmith, B. 351 Golutvina, M.M. 201 Goodman, J.F. 113 Gorelov, S.L. 358 Gorodetchkaya, A.V. 105 Gorodetskaja, A.V. 265 Gorodetskaya, A.V. 114 Gorodetzkaja, A. 17, 37, 152, 272 Gortikov, V.M. 272 Green-Kelly, R. 185 Grigorov, O.N. 201 Gross, E.P. 336 Guggenheim, E. 152 Gutop, Yu.V. 114, 184 Haase, R. 190 Hachisu, Sei 113 Hamaker, H. 18, 22, 26, 28, 32, 73, 202 Hamaker, H.C. 104 Hardy, W. 104, 105, 266 Hardy, W.B. 26 Harkins, W.D. 337 Harper, W.R. 351 Haydon, D.A. 113 Haynes, J.M. 222, 240 Healy, T.H. 337 Herker, M. 108 Hiller, R. 351 Hoekstra, P. 213, 222, 240 Houwink, R. 22, 33
AUTHOR INDEX Ii'ichiev, A.V. 358 Ingram, B.I. 113 Israelachvili, J.N. 114, 121 Ivanishchenko, N. 272 Ivchenko, I.N. 331 Ivchenko, Y.I. 309 Izmailova, G.I. 337 Jalamov, Yu.J. 114 Jeans, J. 19 Jellinek, H.H.G. 213, 222, 240 John, W. 350 Johnson, K.L. 351 Jordan, D.W. 351 Jumikis, A.R. 222, 240 Kabanov, B. 105, 272 Kabanov, B.N. 105, 184, 265 Kallmann, H. 31, 104 Kapkin, M.M. 222, 240 Karas(s)ev, V.V. 184, 185, 202, 207, 265, 266 Karlov, N.V. 358 Katisheva, A.S. 240 Katysheva, A.S. 222 Kaverina, N.I. 266 Kay, B.D. 222, 240 Keesom, W. 331 Kendall, K. 351 Kerker, M. 358 Keuskamp, J.W. 113 Khaimov-Mal'kov, V.Ya. 222, 231, 240 Khainman, V.Ya. 266 Khomutov, A.M. 185 Kibel, I.A. 3009 Kirilenko, N.V. 213, 221, 239 Kirkwood, G. 272 Kirkwood, J.G. 113 Kiselev, G.P. 127 Kiselev, V.F. 213, 222, 231, 240 Kiselev, V.I. 231 Kiseleva, E. 266 Kiseleva, E.V. 185, 201 Kiseleva, O.A. 222, 231, 240 Kitchener, J.A. 114, 184, 231 Klassen, V.I. 266 Knight, C.A. 231 Knudsen, M. 301, 331 Kobzareva, S.A. 202 Kocherga, I.I. 127 Kochin, N.E. 309 Kodochigov, P.N. 201 Kogan, M.N. 336 Komarov, I.A. 222, 240 Kondo, S. 213 Koptelova, B.V. 113
Koptelova, M.M. 121, 185, 201 Koretsky, A.F. 113 Korff, I. 34, 73, 114 Korotkova, A.A. 185 Kose, Akira 113 Krotova, N.A. 350 Kruger, A.J. 231 Kruglyakov, P.M. 113 Krupp, H. 351 Kruyt, H.R. 190 Kuchukov, E.Z. 222, 240 Kudrjavceva, N.M. 104 Kudryavtsev, V.A. 222, 240 Kudryavtseva, N.M. 114 Kudryavzeva, N.M. 121 Kunio Aoto 73 Kurazaev, A.B. 222 Kurbatov, L.P. 185 Kurghen, Iu.S. 337 Kurilenko, O.D. 127 Kurzaev, A.B. 213, 222, 231, 240 Kus(s)akov, M. 13, 16, 24, 33, 73, 151 Kus(s)akov, M.M. 82, 104, 113, 121, 184, 202, 213, 265 Kuzina, A.F. 201 Kuz'mina, Z.N. 201 Kvlividze, A.B. 213 Kvlividze, V.I. 213, 222, 231, 240 LaMer, V.K. 337 Landau, L. 105, 136, 151 Landau, L.D. 73, 104, 108, 113, 184, 190, 265, 272, 309, 336, 351 Langmuir, A. 152 Langmuir, D.B. 337 Langmuir, I. 17, 30, 37, 113, 121, 265, 266, 337 Lebedeva, L. 113, 151 Lebedeva, L.A. 184 Leib, F. 114 Leja, J. 266 Leonov, L.F. 337 Levdanskii, V.V. 358 Levi, S.M. 104, 105 Levich, V. 136 Levich, V.G. 104, 265 Levin, L.M. 265 Levine, S. 18, 37 Lifshits, E.M. 114, 127, 158, 165, 201, 309, 336 Lifshitz, E.M. 108, 121, 266, 272, 351 Lin, S.P. 358 Ling, G.N. 127 Lisichenko, V.A. 265
AUTHOR
4
INDEX
Loch, P.G. 222, 240 Loffler, F. 351 Lonsdale, H.K. 127 Lookyanovich 73 Lopatina, A.M. 185 Los, J.R. 331 LSw-Beer, P. 17, 81 Loyalka, S.K. 336 Luiken, B. 272 Luzhnov, Yu.M. 207 Lyklema, J. 113 Lykov, A.V. 190
Onsager, L. 152 Osager, L. 113 Ostroumov, V.V. 201 Ostwald, Wo 35, 54 Ottewill, R.H. 104 Ouwens, C.H.T. 231 O v c h a r e n k o , F.D. 127 Overbeek, G. 81 Overbeek, I.Th.G. 113, 114 Overbeek, J.Th. 73, 105, 114 Overbeek, J.Th.G. 81, 113, 184, 265
Mackor, E.L. 121 Malkina, A.D. 82, 265 M a l y s h e v a , D.S. 207 Manev, E. 113 March, A. I, 30 M a r k o v i c h , A.V. 201 Martinov, G.A. 114 Martynov, G.A. 184 Masing, G. 105 Matijevic, E. 108 Maxwell, J.C. 331 Mayland, H.F. 222, 240 Mazur, P. 336 McBain, J. 152 M e d v e d o v s k u , V. 105 M e l ' n i k o v a , M.K. 190, 231 Metsik, M.S. 185 Metzik, M.S. 113 Miaw, H.L. 266 Mikhovich, N.S. 351 Milekhina, M.M. 201 Miller, R.D. 213, 222, 240 M i l y o k h i n a , M.M. 185 M i t r o f a n o v , S.I. 266 Mogilat, S.V. 337 Mokrousov, V.A. 266 Moskvin, V.M. 222, 240 M o s k v i t i n , N.I. 266 Muller, M.M. 121 Muller, V.M. 114, 350, 351 Mysels, K. 105 Mysels, K.J. 113
Pashley, R.M. 231 Paw, U.K.T. 351 Peschel, G. 113, 121 p f ~ t z e n r e u t e r , A. 105 Philippoff, W. 265 Pichugin, E.F. 207 Pichyugin, E. 152 Pitaevskii, L.P. 201 Pitaevsklj, L.P. 114 Pitaevsky, A.D. 127 Pitaevsky, L.P. 113 Pitaevsky, L.S. 121 P i t a y e v s k y , L.P. 165, 266 Plaskin, I.N. 266 Platikanov, D. 113, 185 Podnek, A.K. 266 Polder, D. 73, 108, 114, 266 Polezhaev, V.I. 331 Popov, B.G. 351 P o p o v s k y , Yu.M. 185 Powis, F. 55, 56, '57 Preining, O. 358 Prokhorov, A.M. 358 Prokhorov, P.S. 337 Prosser, A.P. 114 Prosser, A.V. 184
Nechaev, E.A. 222, 240 Nekrasov, N. 272 Nerpin, S.V. 104, 184, 198, 222, 231, 240 Nersesova, Z.A. 222, 240 Netzel, J. 127 Ninham, B.W. 121 Novikova, A.V. 231 Nutting, G.C. 337 Obuchov, Obuchov, Ono, S.
E. 26 E.V. 104, 213
113
R a b i n o v i c h , Ya.I. 121, 231, 331, 336 Radke, C. 121 Radushkevich 73 Rao, A.K. 351 Rehbinder, P. 22, 82 Rehbinder, P.A. 113, 222, 240, 266, 272 Reischl, G. 350 Richmond, P. 114 Rideal, E. 351 Roberts, A.D. 351 Romanov, V.P. 222, 240 R~mkens, M.J.M. 213 Rosano, H. 337 Rose, N.V. 309 Rosenhead, L. 38 R o s e n z w e i g , L.A. 337
AUTHOR R o u w e l e r , G.C.J. 114 Rovin, Yu.G. 113 Rubel, G.O. 337 Rusanov, A . I . 113 Samartsev, A.G. 201 Sanfeld, A. 113 Sapon, I.P. 184 Savitski, A.N. 240 Savitskii, A.N. 222 Saweris, Z. 185 Schaeffer, V.J. 337 Scheludko, A.D. 184, 185 Schlyigin, A. 105 Schmidt, G. 331 Schnorrer, R. 113 Schukin, E.D. 113 Schulman, J.H. 266 Scott, W.S. 222, 240 Sedunov, Yu.S. 338 S e r e b r o v s k a y a , M.V. 114 Shagly, E.I. 337 Shalaguin, A.M. 358 Sheludko, A. 105, 113 Sheludko, A.D. 104, 113, 121 Shereshefsky, I.L. 185 Shinoda, K. 105 Shukakidze, N.D. 184 Shustov, V.A. 337 Shutor, S.V. 185 Shutor, Yu. 190 S i d o r e n k h o v , G. 266 Sidorenkov, G.G. 201, 266 Sidorenkov, G.P. 113, 165, 184, 185, 190, 213, 222, 231, 240 Sitarski, M. 358 Slater, J.C. 272 Smilga, V.P. 350 Smith, T.D. 266 S m o l u c h o v s k i , M. 73, 301 S m o l u c h o w s k y , M. 2 Sobolev, V.D. 113, 213, 221, 222, 231, 239, 240 Sokolova, Z°A. 201 Solomentseva, I.M. 127 Sonntag, H. 113, 127 Soo, S.L. 351 Sorokin, V. N. 331 Sparnaay, M.J. 114, 184 Spedden, H.R. 266 Spielman, L.A. 114 Spitsyn, V.I. 201 S p l i t t g e r b e r , H. 114 Squires, P. 338 Starostin, A.N. 358 Stockman, M°I. 358 S t o r o z h i l o v a , A.I. 331 S t r a k h o v s k i i , G.M. 207
INDEX
Strenge, K. 113 Suetin, P.E. 336 Sukhovolskaj a 82 Sutherland, K.L. 266 S v e n - N i l s s o n , I. 265 Symons, P.C. 113 Tabor, D. 114 Tabor, I. 114 Talmud, D.L. 82 Taube, P.R. 113 Taylor, J.L. 113 Taylor, P.W. 207 Teleguin, G.G. 358 Thompson, W.J. 320, 337 T i t e v s k a y a , A.S. 114 T i t i e v s k a j a , A.S. 265, 272 T i t i e v s k a y a , A.S. 104, 113 T i t i j e v s k a j a , A.S. 73, 82 T i t i y e v s k a y a , A.S. 105 T i t j e v s k a j a, A. 24 T i t j e v s k a y a , A. 104, 105 Todes, O.M. 320 Tong, N.T. 358 Toporov, ¥u.P. 350, 351 T r a p e z n i k o v , A.A. 82, 337 T s i t o v i c h , N.A. 240 Tsvetkov, V.N. 207 T s y t o v i c h , N.A. 222 Tyoku Matuhasi 73 U n t e r b e r g e r , B. 127 Ushakova, L.A. 231 Usyarov, O.G. 114 V a k s m a n n , M.A. 358 van den Tempel 105 v a n G r u d n e r b e e c k , F. 104 v a n Silfhout, A. 114 Velde, K. 231 Vershinin, P.V. 213, 221, 239 Verway, E.J.W. 184 Verwey, E. 81, 113, 114 Verwey, E.J. 73, 105, 265 Vignes, M. 213, 222, 240 V i g n e s - A d l e r , J. 222 V i g n e s - A d l e r , M. 213, 240 Visser, J. 351 Vlasenko, G.J. 104 Vlasov, A.A. 207 Volova, M.L. 265 V o r o p a e v a , T.N. 105 V o r o p a y e v a , T.N. 184, 265 V o r o s h i l o v , G.D. 222, 240 Voznij, P.A. 231 Voznyi, P.A. 222, 240 W a l d m a n n , L. Wannop, G.L.
286, 351
358
AUTHOR Wark, I.W. 266 Warner, J. 338 Watillon, A. 104 Weber, S. 331 WenstrSm, E. 22, 82 Whitby, K.T. 351 Whitfild, R. 351 Wilkins, D.I. 104 W i l l s t M t t e r , M. 31, 104 W i n t e r t o n , R.H.S. 114 W i t t m a n n , F. 114 Yalamov, Y.I. 308, 309 Yalamov, Yu.I. 331, 358 Yanis, N.A. 266 Y a r m a k o v s k i , V.N. 240 Y a r m a k o v s k i i , V.N. 222 Yaroshchuk, A.E. 127 Yashin, V.N. 114 Yeh, H.C. 351 Yushchenko, V.S. 351 Yuzhnij, Z.M. 331
INDEX
Zakjavayeva, N.N. 185 Zhdanov, V.M. 358 Zheleznij, B.V. 239 Zheleznyi, B.V. 221 Zhestkova, T.N. 222, 240 Zhilenkov, I.V. 185 Zhukhovitskij, E.M. 331 Zhukov, I.I. 202 Ziegler, P. 351 Ziering, S. 336 Zimon, A.D. 351 Zisman, W.A. 207 Zocher, H. 17, 81 Zolotarev, P.P. 190 Zorin, Z.M. 113, 121, 185, 221, 222, 231, 239, 240, 265, 266 Zubaschenko, E.A. 165, 185 201, 266 Zvonareva, G.V. 222, 240
PROGRESS IN SURFACE SCIENCE, VOLUME 43 SUBJECT INDEX
Adhesion heterocoagulation and convex surfaces 72 plane surfaces 68-71 strongly charged surfaces 71-72 Aerosol dynamics 273-358 Aerosol particles behavior in nonuniformly heated gaseous mixture 281-286 distribution, gas molecules over velocities 281-282 kinetic theory of gases and 281 in neighborhood of CCl 4 drop in helium 285-286 in neighborhood of growing or evaporating drop 284-285 temperature and concentration gradients and 281 velocity, directed 283-284 diffusiophoresis of 277-280 photophoresis of in laser-excited gas 352-358 thermophoresis velocity of coefficient of thermal slip and 321-330 horizontal method 323-327 slit method 327-330 theoretical methods 322-323, 329 volatile thermophoresis of 302-306 Binary solutions molecular-surface forces in. See Molecular-surface forces, in binary solutions Boundary layer of liquids kinetic phenomena in 138-151 applications 150-151 boundary viscosity 139-140 capillary osmosis: definition and investigation 145-148
(Boundary layer...capillary) alcohol-water case 147-148 disjoining pressure, liquidsolid interface 138 electro-osmosis analogue 142-145 electrophoresis and slip 145 flow potential analogue 138-141 force detection, particles in solution 148-150 potential gradient formation, fall of particles in liquid 141-142 pressure gradient across capillary 139 velocities profile 139-140 Caoutchouc latex films deposition of diffusiophoresis in electrolyte solutions and 153-158 Capillary osmosis definition and investigation in boundary layers of liquids 145-148 molecular-surface forces in binary solutions 161-165 Capillary osmosis theory radioactive tracer study of 191-201 liquid slip on solid wall 191-195 measurement methods in 195-196 processing of data 196-198 results and discussion 198-201 Capillary surfaces, thermoosmotic flow of wetting films of water 186-190 Cetyl alcohol vapors passivating effect on condensation growth salt solution drops 315-320
8
SUBJECT INDEX
(Cetyl alcohol...passivating) water drops 310-315 Coagulation criterion of 30-33 of dissimilar particles. See Heterocoagulation electrolyte electromagnetic retardation of 107-108 kinetics of of lyophobic colloids in disperse systems 2, 10-14 of lyophobic sols and suspensions 50-53 slow lyophobic colloids in disperse systems 22-23 of sols and suspensions 50-53 of weakly charged sols 33-34 Colloid particles charged repulsive forces between and slow coagulation 15-27. See also Repulsive forces in disperse systems electric double layer influence 1-14 lyophobic in disperse systems coagulation kinetics and 2, 10-14 interaction of 5-9, 28-29 large radii 5-7, 28-29 small radii 8-9 slow coagulation and stability of 22-23 stability of 1-14 Colloid stability surface forces and 83-104. See also Surface forces Colloid stability theory 115-121 factors affecting 109-113 aggregation processes in 109 coagulation kinetics research, flow ultramicroscopy method 112 dispersity of 109 interaction, surface separated by thin interlayers development of theory 111-112 model experimental research 109-111 phase transition in 109
(Colloid Stability...) results of research 112-113 new aspects, conclusions, verifications 115-121 aggregative 115, 116, 119 coagulation kinetics and 118-119 disjoining pressure and 116-117 disperse composition 115, 117, 119 phase transition 115-116, 119 Condensation heterogeneous surfaces forces and 182-184 in thin films and disperse systems 182-184 Condensation growth 310-320, 337-340 of cloud drops adsorption kinetics of surfactant vapor 337-340 passivation of in drops of water and salt solutions 310-320 of salt drops adsorption kinetics of cetyl alcohol vapors and 315-317 computer calculation of 315-317 experimental investigation 317-320 of water drop adsorption kinetics of cetyl alcohol vapors and 310-315 Diffusiophoresis. See also Thermophoresis of aerosol particles 277-280 in electrolyte solution 153-154 deposition of caoutchouc latex films and 154-158 in flotation 248-251 of solid particles in dispersed systems and capillaries 179-180 Disjoining pressure in colloid stability 116-117 in equilibrium thickness phase nonfreezing water films on capillary surface 226-227, 234, 236, 237
SUBJECT INDEX (Disjoining pressure) formation of equilibrium thickness of interlayers frost heaving and 233, 234 free film between bubbles 85-92, 103-104 free film between solids resistance forces in 93-103 in ice interlayer thickening frost heaving and 208-210, 211, 212 Disperse systems stability and interaction of colloid particles in electrical factors in 2-5 particles with large radii 5-7 particles with small radii 8-9 surface forces and, 83-104. See also under Surface forces Dispersion interactions of dissimilar particles 66-68 protected by adsorbed polymers stabilization of 122-127. See also Electrostatic factor Drops cloud surfactant vapor effect on condensation growth 337-340 liquid noncoalescence on contact 273-276 salt solution passivation in condensation growth of 315-320 water passivation in condensation growth of 310-315 Elastic particles collision with rigid surface adhesion force 341-342 contact electrification e f f e c t on 341-350 critical collision velocity 342-344, 345, 347-348, 349, 350 discussion 349-350 role of electric double layer 341-350 theory 344-349 velocity ratio of collision 342-344, 348-349
Electric d o u b l ~ layers particle interaction and stability of lyophobic colloids 1-14 Electrolyte, retardation of coagulating concentration of 107-108 Electrostatic factor stabilization of dispersions protected by adsorbed polymer layers 122-127 anomalous layer model 123-124 barrier height dependence on electrolyte concentration 125-126 concept of undissolving volume in 122 double layer theory and 121-122 electrostatic barrier growth with electrolyte concentration 123 high electrolyte solutions case 124-125 homogeneous adsorption layer and 127 molecular attraction forces and 125, 127 Schulze-Hardy rule and 126 Floatability of antimonite antimonite experiment 270-271 dependence on value of zetapotential 267-271 elementary flotation 267-270 floatability in 270 force barrier in 269 stability criterion of wetting film 268 stages in process 267 van der Waals forces in 267-268 Flotation theory 241-265 interaction in, mineral particle-bubble 241-265 particle attachment in large particles 260-264 precipitation kinetics and small particles 256-260 stages 244-246 surface forces and 241-242 adsorption equilibrium (zone
3)
251-256
diffusiophoretic (zone 2) 248-251 gravity and inertia (zone
1)
246-248
10
SUBJECT INDEX
Free films. See also Liquid films between bubbles disjoining pressure of 85-92 between solids resistance forces and 93 -103 Free films and froths capillary pressure of 74-75 kinetic stability of measurement procedures in 77-78 measurement results 78-79 thinning process in 80-81 static stability of 75-76 Frost damage. See also Nonfreezing interlayers porous solids, flow of nonfreezing water interlayers and 214-222, 232-239 Frost heaving flow of nonfreezing water interlayers in 232-239 influence of pressure and temperature gradients 214 mass exchange in between thawed and frozen zones, porous solid 218-220, 236-237 ice-filled slit pore model 216-218, 232-236 verification 220-221, 237-239 theory of 208-213 disjoining pressure in 208-210, 211, 212 thermocrystal lization pressure in 208-213 Froths. See Free films Gaseous mixture, nonuniformly heated, aerosol particle behavior in 281-286 Gases molecular flow through narrow capillaries angle of incidence 294-295 calculation of mean free paths and flux~ 293-294 conclusions 301 diffusion of nonglancing molecules 296-297 introduction 290-291 Knudsen scattering and 292, 294 methods 291
results 291-292 specular reflection effect at low angles of incidence 290-301 theory 292-300 vaporization rate 296 Heterocoagulation adhesion between convex surfaces 72 of plane surfaces 68-71 strongly charged surfaces 71-72 dispersion interactions, dissimilar particles 66-68 in electrolyte solutions 60-72 applications 72 interaction forces, charged convex surfaces 66 plane-parallel layer 61-65 Kinetics of thin films
129-239
Liquid drops non-coalescence on contact 273-276 air gap profile and 273-274 pressure with diffusion of vapor and 274-276 thickness and 274-276 Liquid films, between surfaces, repulsive forces 24-26 Liquid layer thickness adherence to vessel walls 134-147 on empty vessel walls 129-133 Lyophobic sols stability in disperse systems strongly charged 30-33, 35-53 weakly charged 33-34 Molecular attraction on electrolyte concentration, retardation of 106-108 Molecular-surface forces in binary solutions 159-165 capillary osmosis effect and 161-165 large interface distances 160 rigorous expression of 159-160 small interface distances 160
SUBJECT INDEX N o n f r e e z i n g interlayers mass exchange in between thawed and frozen zones of porous solid 214-221, 232-236 slit model of ice-filled pore 214-221, 232-236 Nonfreezing water films thermocrystallization flow on capillary surface 223-230 mass transfer rate 223-225, 228, 230 N o n f r e e z i n g water interlayers in porous solids frost damage from 214-221 frost heaving from 232-239 Particles. See Aerosol; Colloid; Elastic Passivation of condensation growth cloud drops 337-340 salt solution drops 315-320 water drops 310-315 Photophoresis of particles in gas excited by laser resonance 352-358 discussion of 357-358 gas molecule distribution function in 353-356 m e c h a n i s m of 353 velocity in 356-357 Polydimethylsiloxane (PMS) oligomers boundary viscosity of 203-207 blow-off method 204, 206 as function of distance from solid surface 203-204, 205, 206 profiles during blow-off 206 profiles on glass substrate 205 profiles on steel substrate 206 Repulsive forces electrostatic free energy of charged particles 20-22 interaction of spherical, charged particles 16-20 slow coagulation and stability lyophobic colloid particles 22-23 surfaces separated by liquid films 24-26
Slip. See also Thermal gas slip liquid on solid wall 191-195 Stability of charged lyophobic sols and particle adhesion 30-59 colloids surface forces and 83-104 free films kinetic 77-81 static 75-77 of lyophobic colloids in disperse systems 1-14 slow coagulation and 22-23 of strongly charged lyophobic sols adhesion of particles with convex surfaces 47-49 adhesion of plates 43-47 coagulation criterion and 30-33 coagulation of sols and suspensions 50-53 interaction of plane surfaces 35-43 Supersaturations obtaining constant and uniform 287-289 experimental chamber 289 new method applied 289 present methods for 287 temperature changes and, periodic 287-289 Surface forces disjoining pressure and 85-104. See also Disjoining pressure in flotation theory 241-248 in heterogeneous condensation 182-184 kinetic effects in dispersed systems and capillaries 176-181 blow-off method 180 diffusiophoresis of solid particles 179-180 mechano-caloric 176-171 thermo-osmosis 178-179 stability of colloids and disperse systems 83-104 general theory 85 history of 83-85 lyophobic colloids and 22-23 thermodynamics and 85 surface zone overlap and 166-176 film as single surface of discontinuity 166-167 optical measurements 170
11
12
SUBJECT INDEX
(Surface forces.., zone... ) potential barrier height dependence of method 172-176 surface potential critical value 171-172 thermodynamic treatment 166-167 in thin films and disperse systems in heterogeneous condensation 182-184 kinetic effects in 176-181 surface zone overlap phenomena 166-176 Surfactant vapor passivating effect on condensation growth cloud drops 337-340 Thermal gas slip 332-336 coefficient of direct calculation 332 isothermal heat flux and 332-335 theoretical methods 322-323, 329, 333 velocity of 332, 335, 336 isothermal heat flux, Knudsen layer 332-333 Thermal gas slip coefficient thermomolecular pressure drop measurement 321 aerosol particle motion in temperature gradients 321-322 thermophoresis velocity of aerosol particles and 321-330 discussion experimental results 330 horizontal slit method 323-327 theoretical methods 322-323, 329, 333 vertical slit method 327-330 Thermocapillary flow comparison with thermocrystallization flow 229-230
Thermocrystallization pressure in frost heaving theory 208-213 Thermocrystallization flow nonfreezing water films on capillary surface 223-230 comparison with thermoosmosis 229-230 diffusion rate of vapor and film flow 225, 227-228 disjoining pressure and phase equilibrium in 226-227 mass transfer rate in 223-225, 228, 230 water-ice phase transition heat in 225, 228-229 Thermocrystallization pressure in frost heaving theory 208-213 Thermo-osmosis comparison with thermocrystallization flow 229-230 in dispersed systems and capillaries 178-179 Thermo-osmotic flow wetting films of water on capillary surfaces 186-190 Thermophoresis velocity. See also Diffusiophoresis of aerosol particles, 321-330. See also Aerosol particles, thermophoresis velocity of of volatile aerosol particles 302-306 of volatile droplets 306-308 Thinning process of free films disjoining pressure in 85-92 resistance forces in 92-103 Viscosity, boundary, of polydimethylsiloxane oligomers 203-207
Abricossova, I.I. 265 Abrikosova, I.I. 108, 114, 121, 184, 265, 272 Adam, N. 152 Adamson, I. 82 Adlfinger, K.H. 113 Aidanova, O.S. 185 Akimov, Yu.P. 222, 240 Aktaruzzaman, A.F.M. 358 Alder, B.J. 113 Aleinikova, I.N. 350, 351 Alekseev, O.L. 127 Ananyan, A.A. 221, 240 Anderson, D.M. 213 Andreyev, S.V. 185 Annis, B.K. 331 Archard, I.F. 351 Archer, B.J. 337 Arutunian, M.A. 185 Arutyunyan, M.A. 190 Ash, S.G. 121 Avetisyan, R.A. 337 Aylmore, L.A° 337 Babchin, A. 113 Bakanov, S.P. 280, 286, 331, 336, 358 Balaschova, N.A. 105 Bangham, D.M. 185 Baran, A.A. 127 Barer, S.S. 213, 222, 231, 240 Barnes, G.T. 337 Bartenev, G.M. 351 Batova, G.A. 280, 286 Bazaron, U.B. 202 Belouschek, P. 121 Bergmann, P. 17, 81 Bessonov, S. 266 Bierbrauer, E. 272 Biermans, M. 240 Bigg, E.K. 320 Bigg, E.R. 337 Bikerman, J.J. 185 Black, W. 114, 184 Blodgett, K. 26 Bogdanov, O.S. 266 Boiko, Yu.P. 127 Bondi, A. 207
Borisova, V.M. 337 Brandt, G.H. 222, 240 Bressler, S.E. 82 Brock, J.R. 331 Broddhurst, D. 108 Brownscombe, J.L. 320, 337 Bulgadnaev, A.V. 202 Burgers, W. 22, 33 Buz~goh, A. 35 Cary, J.W. 222, 240 casimir, H. 73, 108 casimir, H.B.G. 266 Cassimir, H.B.G. 114 chaimov-Malkov, V.Ya. 213 Chapman, S. 286, 331 Cheng, L. 351 Cheng, ¥.S. 351 Cherneva, E. 272 Cherny, L.T. 350 Cheverev, V.G. 222, 240 chistolinov, L.V. 240 Chmutov 73 Chmutov, R.V. 185 Christotinov, L.V. 222 Churaev, N.V. 113, 114, 121, 127, 190, 207, 213, 221, 222, 231, 239, 240 Cluny, J.S. 113 Cook, D. 358 Corkill, A. 38 Corkill, J.M. ' 113 Cowling, T. 331 Cowling, T.G. 286 Dahneke, B. 351 Davies, D.K. 351 de Jongh, J.G.V. 114, 184 De Vries, A.J. 184 De Vries, D.A. 240 de Vries, D.A. 231 Defay, R. 113 DeGroot, S.P. 336 Deraguin, B.V. 350 Derjaguin, B. 1, 5, 16, 17, 25, 28, 31, 33, 37, 47, 134, 152, 309 Derjaguin, B.V. 13, 73, 81, 82, 104, 105, 108, 113, I
2 (Derjaguin, B.V., cont.) 114, 121, 127, 151, 158, 165, 213, 231, 239, 240, 265, 266, 272, 308, 320, 331, 336, 337, 351, 358 Deryagin (Derjaguin), B.V. 190, 201, 202, 207, 221, 222, 280, 286, 301 Deryaguin (Derjaguin), B.V. 184, 185 Devor, W. 350 Dijkema, K.M. 213, 222, 240 Distler, G.I. 202 Donnan, F. 31 Dostavalov, B.N. 222 Dostovalov, B.N. 240 Dresner, L. 190 Dube, G. 37 Dukhin, S.S. 127, 158, 165, 185, 201, 265, 266, 280, 286 Dumansky, A.V. 127 Dykhne, A.M. 358 Dzyaloshinski, I.U. 121 Dzyaloshinskij, I.E. 114 Dzyaloshinsky, I.E. 113, 158, 165, 201, 266 Eaborn, C. 207 Ebert, K. 114 Efremova, E.N. 184, 185 Eigeles, M.A. 184, 265 Eilers, H. 34, 73, 114 Einstein, A. 286 Ekserova, D. 121, 184 Ellis, R. 31, 55 Epstein, P. 331 Erschler, B. 152 Ershov, A.P. 190 Ershov, E.D. 222, 240 Ershov, V.A. 337 Ershova, G.F. 121, 231 Ershova, I.G. 222, 240 Esmen, N.A. 351 Evans, L.F. 266 Everett, D.H. 113, 121, 222, 240 Ewers, W.E. 266 Exerova, D. 105 Exzerova, D. 113 Facy, L. 286 Fankuchen 28 Fedoseyev, V.A. 320, 337 Fedyakin, N.N. 185, 301 Fergusson, R.R. 331 Fletcher, N.H. 213, 231, 338 Fox, H.W. 207 Frankel, S. 105 Freundlich, H. 32
AUTHOR
INDEX
Friberg, S. 113 Fridrikhsberg, D.A. 201 Frumkin, A. 17, 37, 152 Frumkin, A.D. 184 Frumkin, A.N. 73, 105, 184, 265, 272 Frumkin, N.A. 105 Fuchs, N. 22, 50 Fuchs, N.A. 114, 320, 338 Fuks, G.I. 105, 266 Fuks, N. 266 Futran, M.F. 266 Gaidukov, M.N. 331 Gaudin, A.M. 266 Gel'mukhanov, F.Kh. 358 Gentry, J.W. 337 Gershuny, F.Z. 331 Gheiner, A.V. 358 Gibbs, W. 152 Gillespie, T. 351 Gilpin, R.R. 222, 240 Glaszman, Yu.M. 184 Glazman, Ju.M. 121 Globus, A.M. 222, 240 Gol'danskii, V.I. 207 Goldshtik, M.A. 331 Goldsmith, B. 351 Golutvina, M.M. 201 Goodman, J.F. 113 Gorelov, S.L. 358 Gorodetchkaya, A.V. 105 Gorodetskaja, A.V. 265 Gorodetskaya, A.V. 114 Gorodetzkaja, A. 17, 37, 152, 272 Gortikov, V.M. 272 Green-Kelly, R. 185 Grigorov, O.N. 201 Gross, E.P. 336 Guggenheim, E. 152 Gutop, Yu.V. 114, 184 Haase, R. 190 Hachisu, Sei 113 Hamaker, H. 18, 22, 26, 28, 32, 73, 202 Hamaker, H.C. 104 Hardy, W. 104, 105, 266 Hardy, W.B. 26 Harkins, W.D. 337 Harper, W.R. 351 Haydon, D.A. 113 Haynes, J.M. 222, 240 Healy, T.H. 337 Herker, M. 108 Hiller, R. 351 Hoekstra, P. 213, 222, 240 Houwink, R. 22, 33
AUTHOR INDEX Ii'ichiev, A.V. 358 Ingram, B.I. 113 Israelachvili, J.N. 114, 121 Ivanishchenko, N. 272 Ivchenko, I.N. 331 Ivchenko, Y.I. 309 Izmailova, G.I. 337 Jalamov, Yu.J. 114 Jeans, J. 19 Jellinek, H.H.G. 213, 222, 240 John, W. 350 Johnson, K.L. 351 Jordan, D.W. 351 Jumikis, A.R. 222, 240 Kabanov, B. 105, 272 Kabanov, B.N. 105, 184, 265 Kallmann, H. 31, 104 Kapkin, M.M. 222, 240 Karas(s)ev, V.V. 184, 185, 202, 207, 265, 266 Karlov, N.V. 358 Katisheva, A.S. 240 Katysheva, A.S. 222 Kaverina, N.I. 266 Kay, B.D. 222, 240 Keesom, W. 331 Kendall, K. 351 Kerker, M. 358 Keuskamp, J.W. 113 Khaimov-Mal'kov, V.Ya. 222, 231, 240 Khainman, V.Ya. 266 Khomutov, A.M. 185 Kibel, I.A. 3009 Kirilenko, N.V. 213, 221, 239 Kirkwood, G. 272 Kirkwood, J.G. 113 Kiselev, G.P. 127 Kiselev, V.F. 213, 222, 231, 240 Kiselev, V.I. 231 Kiseleva, E. 266 Kiseleva, E.V. 185, 201 Kiseleva, O.A. 222, 231, 240 Kitchener, J.A. 114, 184, 231 Klassen, V.I. 266 Knight, C.A. 231 Knudsen, M. 301, 331 Kobzareva, S.A. 202 Kocherga, I.I. 127 Kochin, N.E. 309 Kodochigov, P.N. 201 Kogan, M.N. 336 Komarov, I.A. 222, 240 Kondo, S. 213 Koptelova, B.V. 113
Koptelova, M.M. 121, 185, 201 Koretsky, A.F. 113 Korff, I. 34, 73, 114 Korotkova, A.A. 185 Kose, Akira 113 Krotova, N.A. 350 Kruger, A.J. 231 Kruglyakov, P.M. 113 Krupp, H. 351 Kruyt, H.R. 190 Kuchukov, E.Z. 222, 240 Kudrjavceva, N.M. 104 Kudryavtsev, V.A. 222, 240 Kudryavtseva, N.M. 114 Kudryavzeva, N.M. 121 Kunio Aoto 73 Kurazaev, A.B. 222 Kurbatov, L.P. 185 Kurghen, Iu.S. 337 Kurilenko, O.D. 127 Kurzaev, A.B. 213, 222, 231, 240 Kus(s)akov, M. 13, 16, 24, 33, 73, 151 Kus(s)akov, M.M. 82, 104, 113, 121, 184, 202, 213, 265 Kuzina, A.F. 201 Kuz'mina, Z.N. 201 Kvlividze, A.B. 213 Kvlividze, V.I. 213, 222, 231, 240 LaMer, V.K. 337 Landau, L. 105, 136, 151 Landau, L.D. 73, 104, 108, 113, 184, 190, 265, 272, 309, 336, 351 Langmuir, A. 152 Langmuir, D.B. 337 Langmuir, I. 17, 30, 37, 113, 121, 265, 266, 337 Lebedeva, L. 113, 151 Lebedeva, L.A. 184 Leib, F. 114 Leja, J. 266 Leonov, L.F. 337 Levdanskii, V.V. 358 Levi, S.M. 104, 105 Levich, V. 136 Levich, V.G. 104, 265 Levin, L.M. 265 Levine, S. 18, 37 Lifshits, E.M. 114, 127, 158, 165, 201, 309, 336 Lifshitz, E.M. 108, 121, 266, 272, 351 Lin, S.P. 358 Ling, G.N. 127 Lisichenko, V.A. 265
AUTHOR
4
INDEX
Loch, P.G. 222, 240 Loffler, F. 351 Lonsdale, H.K. 127 Lookyanovich 73 Lopatina, A.M. 185 Los, J.R. 331 LSw-Beer, P. 17, 81 Loyalka, S.K. 336 Luiken, B. 272 Luzhnov, Yu.M. 207 Lyklema, J. 113 Lykov, A.V. 190
Onsager, L. 152 Osager, L. 113 Ostroumov, V.V. 201 Ostwald, Wo 35, 54 Ottewill, R.H. 104 Ouwens, C.H.T. 231 O v c h a r e n k o , F.D. 127 Overbeek, G. 81 Overbeek, I.Th.G. 113, 114 Overbeek, J.Th. 73, 105, 114 Overbeek, J.Th.G. 81, 113, 184, 265
Mackor, E.L. 121 Malkina, A.D. 82, 265 M a l y s h e v a , D.S. 207 Manev, E. 113 March, A. I, 30 M a r k o v i c h , A.V. 201 Martinov, G.A. 114 Martynov, G.A. 184 Masing, G. 105 Matijevic, E. 108 Maxwell, J.C. 331 Mayland, H.F. 222, 240 Mazur, P. 336 McBain, J. 152 M e d v e d o v s k u , V. 105 M e l ' n i k o v a , M.K. 190, 231 Metsik, M.S. 185 Metzik, M.S. 113 Miaw, H.L. 266 Mikhovich, N.S. 351 Milekhina, M.M. 201 Miller, R.D. 213, 222, 240 M i l y o k h i n a , M.M. 185 M i t r o f a n o v , S.I. 266 Mogilat, S.V. 337 Mokrousov, V.A. 266 Moskvin, V.M. 222, 240 M o s k v i t i n , N.I. 266 Muller, M.M. 121 Muller, V.M. 114, 350, 351 Mysels, K. 105 Mysels, K.J. 113
Pashley, R.M. 231 Paw, U.K.T. 351 Peschel, G. 113, 121 p f ~ t z e n r e u t e r , A. 105 Philippoff, W. 265 Pichugin, E.F. 207 Pichyugin, E. 152 Pitaevskii, L.P. 201 Pitaevsklj, L.P. 114 Pitaevsky, A.D. 127 Pitaevsky, L.P. 113 Pitaevsky, L.S. 121 P i t a y e v s k y , L.P. 165, 266 Plaskin, I.N. 266 Platikanov, D. 113, 185 Podnek, A.K. 266 Polder, D. 73, 108, 114, 266 Polezhaev, V.I. 331 Popov, B.G. 351 P o p o v s k y , Yu.M. 185 Powis, F. 55, 56, '57 Preining, O. 358 Prokhorov, A.M. 358 Prokhorov, P.S. 337 Prosser, A.P. 114 Prosser, A.V. 184
Nechaev, E.A. 222, 240 Nekrasov, N. 272 Nerpin, S.V. 104, 184, 198, 222, 231, 240 Nersesova, Z.A. 222, 240 Netzel, J. 127 Ninham, B.W. 121 Novikova, A.V. 231 Nutting, G.C. 337 Obuchov, Obuchov, Ono, S.
E. 26 E.V. 104, 213
113
R a b i n o v i c h , Ya.I. 121, 231, 331, 336 Radke, C. 121 Radushkevich 73 Rao, A.K. 351 Rehbinder, P. 22, 82 Rehbinder, P.A. 113, 222, 240, 266, 272 Reischl, G. 350 Richmond, P. 114 Rideal, E. 351 Roberts, A.D. 351 Romanov, V.P. 222, 240 R~mkens, M.J.M. 213 Rosano, H. 337 Rose, N.V. 309 Rosenhead, L. 38 R o s e n z w e i g , L.A. 337
AUTHOR R o u w e l e r , G.C.J. 114 Rovin, Yu.G. 113 Rubel, G.O. 337 Rusanov, A . I . 113 Samartsev, A.G. 201 Sanfeld, A. 113 Sapon, I.P. 184 Savitski, A.N. 240 Savitskii, A.N. 222 Saweris, Z. 185 Schaeffer, V.J. 337 Scheludko, A.D. 184, 185 Schlyigin, A. 105 Schmidt, G. 331 Schnorrer, R. 113 Schukin, E.D. 113 Schulman, J.H. 266 Scott, W.S. 222, 240 Sedunov, Yu.S. 338 S e r e b r o v s k a y a , M.V. 114 Shagly, E.I. 337 Shalaguin, A.M. 358 Sheludko, A. 105, 113 Sheludko, A.D. 104, 113, 121 Shereshefsky, I.L. 185 Shinoda, K. 105 Shukakidze, N.D. 184 Shustov, V.A. 337 Shutor, S.V. 185 Shutor, Yu. 190 S i d o r e n k h o v , G. 266 Sidorenkov, G.G. 201, 266 Sidorenkov, G.P. 113, 165, 184, 185, 190, 213, 222, 231, 240 Sitarski, M. 358 Slater, J.C. 272 Smilga, V.P. 350 Smith, T.D. 266 S m o l u c h o v s k i , M. 73, 301 S m o l u c h o w s k y , M. 2 Sobolev, V.D. 113, 213, 221, 222, 231, 239, 240 Sokolova, Z°A. 201 Solomentseva, I.M. 127 Sonntag, H. 113, 127 Soo, S.L. 351 Sorokin, V. N. 331 Sparnaay, M.J. 114, 184 Spedden, H.R. 266 Spielman, L.A. 114 Spitsyn, V.I. 201 S p l i t t g e r b e r , H. 114 Squires, P. 338 Starostin, A.N. 358 Stockman, M°I. 358 S t o r o z h i l o v a , A.I. 331 S t r a k h o v s k i i , G.M. 207
INDEX
Strenge, K. 113 Suetin, P.E. 336 Sukhovolskaj a 82 Sutherland, K.L. 266 S v e n - N i l s s o n , I. 265 Symons, P.C. 113 Tabor, D. 114 Tabor, I. 114 Talmud, D.L. 82 Taube, P.R. 113 Taylor, J.L. 113 Taylor, P.W. 207 Teleguin, G.G. 358 Thompson, W.J. 320, 337 T i t e v s k a y a , A.S. 114 T i t i e v s k a j a , A.S. 265, 272 T i t i e v s k a y a , A.S. 104, 113 T i t i j e v s k a j a , A.S. 73, 82 T i t i y e v s k a y a , A.S. 105 T i t j e v s k a j a, A. 24 T i t j e v s k a y a , A. 104, 105 Todes, O.M. 320 Tong, N.T. 358 Toporov, ¥u.P. 350, 351 T r a p e z n i k o v , A.A. 82, 337 T s i t o v i c h , N.A. 240 Tsvetkov, V.N. 207 T s y t o v i c h , N.A. 222 Tyoku Matuhasi 73 U n t e r b e r g e r , B. 127 Ushakova, L.A. 231 Usyarov, O.G. 114 V a k s m a n n , M.A. 358 van den Tempel 105 v a n G r u d n e r b e e c k , F. 104 v a n Silfhout, A. 114 Velde, K. 231 Vershinin, P.V. 213, 221, 239 Verway, E.J.W. 184 Verwey, E. 81, 113, 114 Verwey, E.J. 73, 105, 265 Vignes, M. 213, 222, 240 V i g n e s - A d l e r , J. 222 V i g n e s - A d l e r , M. 213, 240 Visser, J. 351 Vlasenko, G.J. 104 Vlasov, A.A. 207 Volova, M.L. 265 V o r o p a e v a , T.N. 105 V o r o p a y e v a , T.N. 184, 265 V o r o s h i l o v , G.D. 222, 240 Voznij, P.A. 231 Voznyi, P.A. 222, 240 W a l d m a n n , L. Wannop, G.L.
286, 351
358
AUTHOR Wark, I.W. 266 Warner, J. 338 Watillon, A. 104 Weber, S. 331 WenstrSm, E. 22, 82 Whitby, K.T. 351 Whitfild, R. 351 Wilkins, D.I. 104 W i l l s t M t t e r , M. 31, 104 W i n t e r t o n , R.H.S. 114 W i t t m a n n , F. 114 Yalamov, Y.I. 308, 309 Yalamov, Yu.I. 331, 358 Yanis, N.A. 266 Y a r m a k o v s k i , V.N. 240 Y a r m a k o v s k i i , V.N. 222 Yaroshchuk, A.E. 127 Yashin, V.N. 114 Yeh, H.C. 351 Yushchenko, V.S. 351 Yuzhnij, Z.M. 331
INDEX
Zakjavayeva, N.N. 185 Zhdanov, V.M. 358 Zheleznij, B.V. 239 Zheleznyi, B.V. 221 Zhestkova, T.N. 222, 240 Zhilenkov, I.V. 185 Zhukhovitskij, E.M. 331 Zhukov, I.I. 202 Ziegler, P. 351 Ziering, S. 336 Zimon, A.D. 351 Zisman, W.A. 207 Zocher, H. 17, 81 Zolotarev, P.P. 190 Zorin, Z.M. 113, 121, 185, 221, 222, 231, 239, 240, 265, 266 Zubaschenko, E.A. 165, 185 201, 266 Zvonareva, G.V. 222, 240
PROGRESS IN SURFACE SCIENCE, VOLUME 43 SUBJECT INDEX
Adhesion heterocoagulation and convex surfaces 72 plane surfaces 68-71 strongly charged surfaces 71-72 Aerosol dynamics 273-358 Aerosol particles behavior in nonuniformly heated gaseous mixture 281-286 distribution, gas molecules over velocities 281-282 kinetic theory of gases and 281 in neighborhood of CCl 4 drop in helium 285-286 in neighborhood of growing or evaporating drop 284-285 temperature and concentration gradients and 281 velocity, directed 283-284 diffusiophoresis of 277-280 photophoresis of in laser-excited gas 352-358 thermophoresis velocity of coefficient of thermal slip and 321-330 horizontal method 323-327 slit method 327-330 theoretical methods 322-323, 329 volatile thermophoresis of 302-306 Binary solutions molecular-surface forces in. See Molecular-surface forces, in binary solutions Boundary layer of liquids kinetic phenomena in 138-151 applications 150-151 boundary viscosity 139-140 capillary osmosis: definition and investigation 145-148
(Boundary layer...capillary) alcohol-water case 147-148 disjoining pressure, liquidsolid interface 138 electro-osmosis analogue 142-145 electrophoresis and slip 145 flow potential analogue 138-141 force detection, particles in solution 148-150 potential gradient formation, fall of particles in liquid 141-142 pressure gradient across capillary 139 velocities profile 139-140 Caoutchouc latex films deposition of diffusiophoresis in electrolyte solutions and 153-158 Capillary osmosis definition and investigation in boundary layers of liquids 145-148 molecular-surface forces in binary solutions 161-165 Capillary osmosis theory radioactive tracer study of 191-201 liquid slip on solid wall 191-195 measurement methods in 195-196 processing of data 196-198 results and discussion 198-201 Capillary surfaces, thermoosmotic flow of wetting films of water 186-190 Cetyl alcohol vapors passivating effect on condensation growth salt solution drops 315-320
8
SUBJECT INDEX
(Cetyl alcohol...passivating) water drops 310-315 Coagulation criterion of 30-33 of dissimilar particles. See Heterocoagulation electrolyte electromagnetic retardation of 107-108 kinetics of of lyophobic colloids in disperse systems 2, 10-14 of lyophobic sols and suspensions 50-53 slow lyophobic colloids in disperse systems 22-23 of sols and suspensions 50-53 of weakly charged sols 33-34 Colloid particles charged repulsive forces between and slow coagulation 15-27. See also Repulsive forces in disperse systems electric double layer influence 1-14 lyophobic in disperse systems coagulation kinetics and 2, 10-14 interaction of 5-9, 28-29 large radii 5-7, 28-29 small radii 8-9 slow coagulation and stability of 22-23 stability of 1-14 Colloid stability surface forces and 83-104. See also Surface forces Colloid stability theory 115-121 factors affecting 109-113 aggregation processes in 109 coagulation kinetics research, flow ultramicroscopy method 112 dispersity of 109 interaction, surface separated by thin interlayers development of theory 111-112 model experimental research 109-111 phase transition in 109
(Colloid Stability...) results of research 112-113 new aspects, conclusions, verifications 115-121 aggregative 115, 116, 119 coagulation kinetics and 118-119 disjoining pressure and 116-117 disperse composition 115, 117, 119 phase transition 115-116, 119 Condensation heterogeneous surfaces forces and 182-184 in thin films and disperse systems 182-184 Condensation growth 310-320, 337-340 of cloud drops adsorption kinetics of surfactant vapor 337-340 passivation of in drops of water and salt solutions 310-320 of salt drops adsorption kinetics of cetyl alcohol vapors and 315-317 computer calculation of 315-317 experimental investigation 317-320 of water drop adsorption kinetics of cetyl alcohol vapors and 310-315 Diffusiophoresis. See also Thermophoresis of aerosol particles 277-280 in electrolyte solution 153-154 deposition of caoutchouc latex films and 154-158 in flotation 248-251 of solid particles in dispersed systems and capillaries 179-180 Disjoining pressure in colloid stability 116-117 in equilibrium thickness phase nonfreezing water films on capillary surface 226-227, 234, 236, 237
SUBJECT INDEX (Disjoining pressure) formation of equilibrium thickness of interlayers frost heaving and 233, 234 free film between bubbles 85-92, 103-104 free film between solids resistance forces in 93-103 in ice interlayer thickening frost heaving and 208-210, 211, 212 Disperse systems stability and interaction of colloid particles in electrical factors in 2-5 particles with large radii 5-7 particles with small radii 8-9 surface forces and, 83-104. See also under Surface forces Dispersion interactions of dissimilar particles 66-68 protected by adsorbed polymers stabilization of 122-127. See also Electrostatic factor Drops cloud surfactant vapor effect on condensation growth 337-340 liquid noncoalescence on contact 273-276 salt solution passivation in condensation growth of 315-320 water passivation in condensation growth of 310-315 Elastic particles collision with rigid surface adhesion force 341-342 contact electrification e f f e c t on 341-350 critical collision velocity 342-344, 345, 347-348, 349, 350 discussion 349-350 role of electric double layer 341-350 theory 344-349 velocity ratio of collision 342-344, 348-349
Electric d o u b l ~ layers particle interaction and stability of lyophobic colloids 1-14 Electrolyte, retardation of coagulating concentration of 107-108 Electrostatic factor stabilization of dispersions protected by adsorbed polymer layers 122-127 anomalous layer model 123-124 barrier height dependence on electrolyte concentration 125-126 concept of undissolving volume in 122 double layer theory and 121-122 electrostatic barrier growth with electrolyte concentration 123 high electrolyte solutions case 124-125 homogeneous adsorption layer and 127 molecular attraction forces and 125, 127 Schulze-Hardy rule and 126 Floatability of antimonite antimonite experiment 270-271 dependence on value of zetapotential 267-271 elementary flotation 267-270 floatability in 270 force barrier in 269 stability criterion of wetting film 268 stages in process 267 van der Waals forces in 267-268 Flotation theory 241-265 interaction in, mineral particle-bubble 241-265 particle attachment in large particles 260-264 precipitation kinetics and small particles 256-260 stages 244-246 surface forces and 241-242 adsorption equilibrium (zone
3)
251-256
diffusiophoretic (zone 2) 248-251 gravity and inertia (zone
1)
246-248
10
SUBJECT INDEX
Free films. See also Liquid films between bubbles disjoining pressure of 85-92 between solids resistance forces and 93 -103 Free films and froths capillary pressure of 74-75 kinetic stability of measurement procedures in 77-78 measurement results 78-79 thinning process in 80-81 static stability of 75-76 Frost damage. See also Nonfreezing interlayers porous solids, flow of nonfreezing water interlayers and 214-222, 232-239 Frost heaving flow of nonfreezing water interlayers in 232-239 influence of pressure and temperature gradients 214 mass exchange in between thawed and frozen zones, porous solid 218-220, 236-237 ice-filled slit pore model 216-218, 232-236 verification 220-221, 237-239 theory of 208-213 disjoining pressure in 208-210, 211, 212 thermocrystal lization pressure in 208-213 Froths. See Free films Gaseous mixture, nonuniformly heated, aerosol particle behavior in 281-286 Gases molecular flow through narrow capillaries angle of incidence 294-295 calculation of mean free paths and flux~ 293-294 conclusions 301 diffusion of nonglancing molecules 296-297 introduction 290-291 Knudsen scattering and 292, 294 methods 291
results 291-292 specular reflection effect at low angles of incidence 290-301 theory 292-300 vaporization rate 296 Heterocoagulation adhesion between convex surfaces 72 of plane surfaces 68-71 strongly charged surfaces 71-72 dispersion interactions, dissimilar particles 66-68 in electrolyte solutions 60-72 applications 72 interaction forces, charged convex surfaces 66 plane-parallel layer 61-65 Kinetics of thin films
129-239
Liquid drops non-coalescence on contact 273-276 air gap profile and 273-274 pressure with diffusion of vapor and 274-276 thickness and 274-276 Liquid films, between surfaces, repulsive forces 24-26 Liquid layer thickness adherence to vessel walls 134-147 on empty vessel walls 129-133 Lyophobic sols stability in disperse systems strongly charged 30-33, 35-53 weakly charged 33-34 Molecular attraction on electrolyte concentration, retardation of 106-108 Molecular-surface forces in binary solutions 159-165 capillary osmosis effect and 161-165 large interface distances 160 rigorous expression of 159-160 small interface distances 160
SUBJECT INDEX N o n f r e e z i n g interlayers mass exchange in between thawed and frozen zones of porous solid 214-221, 232-236 slit model of ice-filled pore 214-221, 232-236 Nonfreezing water films thermocrystallization flow on capillary surface 223-230 mass transfer rate 223-225, 228, 230 N o n f r e e z i n g water interlayers in porous solids frost damage from 214-221 frost heaving from 232-239 Particles. See Aerosol; Colloid; Elastic Passivation of condensation growth cloud drops 337-340 salt solution drops 315-320 water drops 310-315 Photophoresis of particles in gas excited by laser resonance 352-358 discussion of 357-358 gas molecule distribution function in 353-356 m e c h a n i s m of 353 velocity in 356-357 Polydimethylsiloxane (PMS) oligomers boundary viscosity of 203-207 blow-off method 204, 206 as function of distance from solid surface 203-204, 205, 206 profiles during blow-off 206 profiles on glass substrate 205 profiles on steel substrate 206 Repulsive forces electrostatic free energy of charged particles 20-22 interaction of spherical, charged particles 16-20 slow coagulation and stability lyophobic colloid particles 22-23 surfaces separated by liquid films 24-26
Slip. See also Thermal gas slip liquid on solid wall 191-195 Stability of charged lyophobic sols and particle adhesion 30-59 colloids surface forces and 83-104 free films kinetic 77-81 static 75-77 of lyophobic colloids in disperse systems 1-14 slow coagulation and 22-23 of strongly charged lyophobic sols adhesion of particles with convex surfaces 47-49 adhesion of plates 43-47 coagulation criterion and 30-33 coagulation of sols and suspensions 50-53 interaction of plane surfaces 35-43 Supersaturations obtaining constant and uniform 287-289 experimental chamber 289 new method applied 289 present methods for 287 temperature changes and, periodic 287-289 Surface forces disjoining pressure and 85-104. See also Disjoining pressure in flotation theory 241-248 in heterogeneous condensation 182-184 kinetic effects in dispersed systems and capillaries 176-181 blow-off method 180 diffusiophoresis of solid particles 179-180 mechano-caloric 176-171 thermo-osmosis 178-179 stability of colloids and disperse systems 83-104 general theory 85 history of 83-85 lyophobic colloids and 22-23 thermodynamics and 85 surface zone overlap and 166-176 film as single surface of discontinuity 166-167 optical measurements 170
11
12
SUBJECT INDEX
(Surface forces.., zone... ) potential barrier height dependence of method 172-176 surface potential critical value 171-172 thermodynamic treatment 166-167 in thin films and disperse systems in heterogeneous condensation 182-184 kinetic effects in 176-181 surface zone overlap phenomena 166-176 Surfactant vapor passivating effect on condensation growth cloud drops 337-340 Thermal gas slip 332-336 coefficient of direct calculation 332 isothermal heat flux and 332-335 theoretical methods 322-323, 329, 333 velocity of 332, 335, 336 isothermal heat flux, Knudsen layer 332-333 Thermal gas slip coefficient thermomolecular pressure drop measurement 321 aerosol particle motion in temperature gradients 321-322 thermophoresis velocity of aerosol particles and 321-330 discussion experimental results 330 horizontal slit method 323-327 theoretical methods 322-323, 329, 333 vertical slit method 327-330 Thermocapillary flow comparison with thermocrystallization flow 229-230
Thermocrystallization pressure in frost heaving theory 208-213 Thermocrystallization flow nonfreezing water films on capillary surface 223-230 comparison with thermoosmosis 229-230 diffusion rate of vapor and film flow 225, 227-228 disjoining pressure and phase equilibrium in 226-227 mass transfer rate in 223-225, 228, 230 water-ice phase transition heat in 225, 228-229 Thermocrystallization pressure in frost heaving theory 208-213 Thermo-osmosis comparison with thermocrystallization flow 229-230 in dispersed systems and capillaries 178-179 Thermo-osmotic flow wetting films of water on capillary surfaces 186-190 Thermophoresis velocity. See also Diffusiophoresis of aerosol particles, 321-330. See also Aerosol particles, thermophoresis velocity of of volatile aerosol particles 302-306 of volatile droplets 306-308 Thinning process of free films disjoining pressure in 85-92 resistance forces in 92-103 Viscosity, boundary, of polydimethylsiloxane oligomers 203-207