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Missa, Aras: ELSEVIER Journal of Magnetism and Magnetic Materials 201 (1999) 490-495 www.elsevier.com/locate/jmmm Author index to volume 201 Akagami, Y., see Nakatsuka, K. 256 Blums, E., Mass transfer in nonisothermal ferrocolloids Andra, W., see Hiergeist, R. 420 under the effect of a magnetic field 242 Antalik, M., see Koneracka, M. 427 Blums, E., S. Odenbach, A. Mezulis and M. Maiorov, Antohe, L., see Manoliu, Al. 446 Magnetic Soret effect in a hydrocarbon based colloid Anton, I., see Popa, N.C. 385 containing surfacted Mn-Zn ferrite particles 268 Asari, S., see Nakatsuka, K. 256 Bomans, P., see Donselaar, L.N. 58 Aswal, V.K., see Massart, R. 73 Bossis, G. and A. Cebers, Effects of the magnetodipolar Atarashi, T., Y.S. Kim, T. Fujita and K. Nakatsuka, interactions in the alternating magnetic fields 218 Synthesis of ethylene-glycol-based magnetic fluid us- Bossis, G., see Volkova, O. 66 ing silica-coated iron particle 7 Boudouvis, A.G., see Papathanasiou, A.G. 290 Atarashi, T., see Kim, Y.S. 361 Buchin, V.A. and G.A. Shaposhnikova, Suppression of Ayoub, N., see Miller, R. 34 disturbances on the thin film surface of viscous mag- Ayoub, N.Y., R. Mueller, R. Hiergeist and W. Schueppel, netic fluid flowing on the vertical wall 343 A comparative magnetic study of the DC remanence Buining, P.A., see Donselaar, L.N. 58 for the frozen substituted Ba-hexaferrite ferrofluid Buioca, C.D., see Iusan, V. 38 and some conventional frozen ferrofluids 119 Buske, N., see Bashtovoi, V. 332 Azevedo, R.B., see Lacava, Z.G.M. 431 Buske, N., see Hiergeist, R. 420 Butnaru, G., D. Terteac and I. Potencz, Magnetic fluids improving effect in in vitro regenerates in hypograv- Bacri, J.-C., see Hasmonay, E. 195 , whe ' ity conditions 435 Balasoiu, M., see Grabcev, B. 140 Buyanov ee ete Elias Ue 136 Baltag, O. and D. Costandache, Nonlinear behav- peice ae = . iour of the ferrofluid in orthogonal magnetic fields 123 Cader, T., see Tangthieng, C. 252 Baltag, O., see Cotae, C. 394 Calarasu, D., see Cotae, C. 394 Bara, L.1., see Pavel, A. 443 Calarasu, D., C. Cotae and R. Olaru, Magnetic fluid brake 401 Bashtovoi, V., S. Pogirnitskaya and A. Reks, Dynamics Carletto, P., see Volkova, O. 66 of deformation of magnetic fluid flat drops in a homo- Cebers, A., see Volkova, O. 66 geneous longitudinal magnetic field 300 Cebers, A., see Bossis, G. 218 Bashtovoi, V., P. Kuzhir and A. Reks, Statics of magnetic Cebers, A., see Drikis, I. 339 fluid drop in channels of various forms 328 Charles, S.W., see Fannin, P.C. 91 Bashtovoi, V., A. Reks, L. Suloeva, A. Sukhotsky, A. Charles, S.W., see Fannin, P.C. 98 Nethe, N.D. Stahlmann, N. Buske and P. Killat, Charles, S.W., see Fannin, P.C. 113 Study of ponderomotive interaction of magnetic field Chetverikov, M.V., see Engel, A. 310 sources in a magnetic fluid 332 Chiou, Y.C., see Yang, H.C. 313 Bibicu, I., see Mihalca, I. 53 Chiou, Y.C., see Jang, IJ. 317 Bica, D., see Grabcev, B. 140 Claici, F., see Hrianca, I. 126 Bica, D., see Vekas, L. 159 Coroiu, 1., Relaxivities of different superparamagnetic Bica, D., see Jamon, D. 174 particles for application in NMR tomography 449 Bica, I., Plasma device for magnetic nanoparticles pro- Costandache, D., see Baltag, O. 123 duction 45 Costandache, D., see Cotae, C. 394 Blom, C., see de Gans, B.J. 11 Cotae, C., O. Baltag, R. Olaru, D. Calarasu and D. Blums, E., see Wagener, M. 18 Costandache, The study of a magnetic fluid-based Blums, E., see Maiorov, M. 95 sensor 394 0304-8853/99/$s-e e front matter © 1999 Elsevier Science B.V. All rights reserved. PII: S0304-8853(99)00439-4 Author index to volume 201 Cotae, C., see Calarasu, D. 401 Fujita, T., see Atarashi, T. Cotae, C., see Pavel, A. 443 Fujita, T., T. Miyazaki, H. Nishiyama and B. Jeyadevan, Cotae, C., see Manoliu, Al. 446 Preparation and properties of low boiling point of Creanga, D.E., see Pavel, A. 443 alcohol and acetone-based magnetic fluid Creanga, D.E., see Manoliu, Al. 446 Fujita, T., see Kim, Y.S. Cser, L., see Lebedev, V.T. 80 Cser, L., see Lebedev, V.T. 133 Garcia, V.A.P., see Lacava, Z.G.M. Cser, L., see Lebedev, V.T. 136 Gendron, F., see Massart, R. Cutillas, S., see Volkova, O. 66 Gendron, F., see Zins, D. Czechowski, G., see Potocova, I. 163 Gheorghe, D., see Vekas, L. Gillis, P., see Roch, A. Da Silva, M.F., see Lacava, Z.G.M. 431 Gilly, H., see Odenbach, S. Da Silva, S.W., see Morais, P.C. 105 Gordeev, G.P., see Lebedev, V.T. De Gans, B.J., C. Blom, J. Mellema and A.P. Philipse, Goyal, P.S., see Massart, R. Preparation and magnetisation of a silica-magnetite Grabcev, B., M. Balasoiu, A. Tirziu, A.I. Kuklin and D. inverse ferrofluid Bica, Application of contrast variation method in De Sabata, I., see Popa, N.C. SANS experiments with ferrofluids Depeyrot, J., see Hasmonay, E. Ginther, B., see Wagener, M. Donatini, F., see Jamon, D. Giinther, B., see Wagener, M. Donatini, F., see Payet, B. Donselaar, L.N., P.M. Frederik, P. Bomans, P.A. Buin- Hadgia, S., see lusan, V. ing, B.M. Humbel and A.P. Philipse, Visualisation of Hadgia, S., V. Iusan and A. Stanci, A method for mag- particle association in magnetic fluids in zero-field netic field determination inside magnetic fluids Dormann, J.L., see Fannin, P.C. Hanson, M., see Maiorov, M. Drikis, I. and A. Cebers, Viscous fingering in magnetic Hasmonay, E., J. Depeyrot, M.H. Sousa, F.A. Tourinho, fluids: numerical simulation of radial Hele-Shaw flow J.-C. Bacri and R. Perzynski, Optical properties of Du, T., see Luo, W. nickel ferrite ferrofluids Hergt, R., see Hiergeist, R. Engel, A.. A. Lange, H. Langer, T. Mahr and M.V. Heyen, M., see Odenbach, S. Chetverikov, A single peak of the Rosensweig insta- Hiergeist, R., see Miller, R. bility Hiergeist, R., see Ayoub, N.Y. Ercuta, A., see Mihalca, I. Hiergeist, R., W. Andra, N. Buske, R. Hergt, I. Hilger, U. Richter and W. Kaiser, Application of magnetite fer- rofluids for hyperthermia Fahling, H., see Jordan, A. Hilger, I., see Hiergeist, R. Fannin, P.C., L. Kinsella and S.W. Charles, Wide-band Hirota, Y., see Matsuno, Y. complex magnetic susceptibility measurements of Hong, C.-Y., Optical switch devices using the magnetic magnetic fluids as a function of temperature fluid thin films Fannin, P.C., S.W. Charles and J.L. Dormann, Field Hong, C.-Y., see Horng, H.E. dependence of the dynamic properties of colloidal Hong, C.-Y., see Yang, H.C. suspensions of Mnpo 66ZNo.34F e204 and Hong, C.-Y., see Jang, LJ. Nip, sZNo,sFe,O,4 particles Horng, H.E., C.-Y. Hong, H.C. Yang, IJ. Jang, S.Y. Fannin, P.C., S.W. Charles and A.T. Skjeltorp, Apparent Yang, J.M. Wu, S.L. Lee and F.C. Kuo, Magnetic superdiamagnetism of diamagnetic spheres in ferrof- field dependence of Cotton—-Mouton rotation for luids magnetic fluid films Fannin, P.C., D. Vincent and G. Noyel, On the measure- Horng, H.E., see Yang, H.C. ment of the complex susceptibility and permittivity of Horng, H.E., see Jang, 1.J. magnetic fluids by means of two different measure- Hrianca, I., I. Maladescu, F. Claici and C.N. Marin, The ment techniques influence of particle concentration in ferrofluids on Felix, R., see Jordan, A. broadening of the magnetic resonance line Ferre, J., see Spoliansky, D. Huang, J., see Luo, W. Filip, O., see Jamon, D. Humbel, B.M., see Donselaar, L.N. Finlayson, B.A., see Tangthieng, C. Frederik, P.M., see Donselaar, L.N. Freitas, M.L.L., see Lacava, Z.G.M. Ikohagi, T., see Sudo, S. Fujisaki, M., see Miiller, R. Ikohagi, T., see Sudo, S. Fujise, T., see Matsuno, Y. Iskakova, L.Yu., see Zubarev, A. Yu. 492 Author index to volume 20] Iskakova, L.Yu., see Zubarev, A.Yu. Klyubin, V.V., see Lebedev, V.T. 80 Iusan, V., C.D. Buioca and S. Hadgia, Magnetic fluids of Kobayashi, N., see Yamaguchi, H. 260 low viscosity Kobori, I., see Yamaguchi, H. 260 Iusan, V., see Stanci, A. Kobori, I., see Yamaguchi, H. 264 Iusan, V., see Hadgia, S. Koneracka, M., see Potoéova, I. 163 Ivanov, A.O. and A.Yu. Zubarev, Kinetics of a ferrofluid Koneracka, M., see Turek, I. 167 phase separation induced by an external magnetic Koneracka, M., see Kopéansky, P. 204 field Koneracka, M., P. Kopéansky, M. Antalik, M. Timko, Ivanov, A.O., Phase separation in magnetic colloids C.N. Ramchand, D. Lobo, R.V. Mehta and R.V. Iwabuchi, M., see Shimada, K. Upadhyay, Immobilization of proteins and enzymes to fine magnetic particles 427 Jadzyn, J., see Potocova, I. Kopcansky, P., see Potoéova, I. 163 Jamet, J.-P., see Spoliansky, D. Kopcansky, P., see Turek, I. 167 Jamon, D., F. Donatini, J. Monin, M. Raga, V. Socoliuc, Kopcansky, P., M. Koneracka, N. TomaSovi¢ova and L. Tomc¢o, The existence of universal angle for magneto- O. Filip, D. Bica and V. Sofonea, Concentration de- pendence of magnetisation and magneto-optical ef- optical effect in magnetic fluids 204 fects in a ferrofluid with double layer stabilized Kopcansky, P., see Koneracka, M. 427 particles 174 Kotitz, R., W. Weitschies, L. Trahms and W. Semmler, Jang, I.J., see Horng, H.E. 215 Investigation of Brownian and Neéel relaxation in Jang, I.J., see Yang, H.C. 313 magnetic fluids 102 Jang, I.J., H.E. Horng, Y.C. Chiou, C.-Y. Hong, J.M. Wu Krakov, M.S., Influence of rheological properties of mag- and H.C. Yang, Pattern formation in microdrops of netic fluid on damping ability of magnetic fluid magnetic fluids 317 shock-absorber 368 Jeyadevan, B. and I. Nakatani, Characterization of field- Kuklin, A.I., see Grabcev, B. 140 induced needle-like structures in ionic and water- Kuo, F.C., see Horng, H.E. 215 based magnetic fluids 62 Kuzhir, P., see Bashtovoi, V. 328 Jeyadevan, B., see Fujita, T. 14 Jeyadevan, B., see Nakatsuka, K. 256 Lacava, L.M., see Lacava, Z.G.M. 431 Johanson, C., see Maiorov, M. 95 Lacava, Z.G.M., R.B. Azevedo, E.V. Martins, L.M. Jorat, L., see Popa, N.C. 398 Lacava, M.L.L. Freitas, V.A.P. Garcia, C.A. Rébula, Jorat, L., see Popa, N.C. 407 A.P.C. Lemos, M.H. Sousa, F.A. Tourinho, M.F. Da Jordan, A., R. Scholz, P. Wust, H. Fahling and R. Felix, Silva and P.C. Morais, Biological effects of magnetic Magnetic fluid hyperthermia (MFH): Cancer treat- fluids: toxicity studies 431 ment with AC magnetic field induced excitation of Lacis, S., Bending of ferrofluid droplet in rotating mag- biocompatible superparamagnetic nanoparticles 413 netic field 335 Lange, A., see Engel, A. 310 Kaiser, W., see Hiergeist, R. 420 Langer, H., see Engel, A. 310 Kali, Gy., see Lebedev, V.T. 80 Lebedev, V.T., G.P. Gordeev, A.I. Sibilev, V.V. Klyubin, Kali, Gy., see Lebedev, V.T. 133 Gy. Torok, L. Cser, Gy. Kali and L.K. Varga, Neu- Kamiyama, S., K. Ueno and Y. Yokota, Numerical anal- tron spin echo study of low-T, ferrofluid 80 ysis of unsteady gas-liquid two-phase flow of mag- Lebedev, V.T., Gy. Torok, Gy. Kali, L. Cser, D.N. Orlova netic fluid 271 and A.I. Sibilev, Dynamics of concentrated ferrofluid Kamiyama, S., see Ueno, K. 281 with labelled particles 133 Kamiyama, S., see Shimada, K. 357 Lebedev, V.T., Gy. Torok, L. Cser, A.L. Buyanov, L.G. Katagiri, K., see Sudo, S. 285 Revelskaya, D.N. Orlova and A.I. Sibilev, Magnetic Katagiri, K., see Sudo, S. 306 phase ordering in ferrogels under applied field 136 Kato, K., N. Umehara and M. Suzuki, A study of hard- Lee, H.S. and I. Nakatani, On the chemical stability of ness of the frozen magnetic fluid grinding wheel iron-nitride magnetic fluids in atmospheric condi- Kawauchi, M., see Umehara, N. tions Kikura, H., Y. Takeda and T. Sawada, Velocity profile Lee, S.L., see Horng, H.E. measurements of magnetic fluid flow using ultrasonic Lemos, A.P.C., see Lacava, Z.G.M. Doppler method Leonard, D., see Segal, V. Killat, P., see Bashtovoi, V. Lindner, P., see Odenbach, S. Kim, Y.S., see Atarashi, T. Lita, M. and M. Nicoara, The use of amorphous and Kim, Y.S., K. Nakatsuka, T. Fujita and T. Atarashi, quasi-amorphous Fe-Cr-P powders for fabrication Application of hydrophilic magnetic fluid to oil seal of magneto-rheological suspensions Kinsella, L., see Fannin, P.C. Lita, M., see Mihalca, I. Author index to volume 201 Lobo, D., see Koneracka, M. 427 Nakatsuka, K., see Kim, Y.S. Luca, D., see Mihalca, I. 53 Naletova, V.A. and V.A. Turkov, Film thickness discon- Luo, W., T. Du and J. Huang, Field-induced instabilities tinuity generation in a magnetic field in a magnetic fluid Nattrass, D., see Segal, V. Nethe, A., see Bashtovoi, V. Mahr, T., see Reimann, B. Nethe, A., T. Sch6ppe and H.-D. Stahlmann, Ferrofluid Mahr, T., see Engel, A. driven actuator for a left ventricular assist device Maiorov, M., E. Blums, M. Hanson and C. Johanson, High Nicoara, M., see Lita, M. field magnetization of the colloidal Mn-Zn ferrite Nishita, T., see Ueno, K. Maiorov, M., see Blums, E. Nishiyama, H., see Fujita, T. Malaescu, I., see Hrianca, I. Nishiyama, H., see Sudo, S. Manoliu, Al., L. Antohe, D.E. Creanga and C. Cotae, The Nishiyama, H., see Sudo, S. influence of the petroleum ferrofluids upon the cellu- Noyel, G., see Fannin, P.C. losolytic fungi Chaetomium globosum Kunze: Fr Noyel, G., see Payet, B. Marin, C.N., see Hrianca, I. Odenbach, S., Microgravity research as a tool for the Martins, E.V., see Lacava, Z.G.M. investigation of effects in magnetic fluids Massart, R., D. Zins, F. Gendron, M. Rivoire, R.V. Odenbach, S., T. Rylewicz and M. Heyen, A rheometer Mehta, R.V. Upadhyay, P.S. Goyal and V.K. Aswal, dedicated for the investigation of viscoelastic effects Electron spin resonance investigation of Mn-Zn in commercial magnetic fluids ionic ferrofluid Odenbach, S., see Blums, E. Matsuno, Y., T. Fujise, K. Tomosawa and Y. Hirota, Odenbach, S., H. Gilly and P. Lindner, The use of mag- Demagnetizing factors of magnetic fluids Maulbetsch, J., see Tangthieng, C. netic small angle neutron scattering for the detection of flow profiles in magnetic fluids Mehta, R.V., see Massart, R. Ohaba, M.., see Sudo, S. Mehta, R.V., see Upadhyay, R.V. Mehta, R.V., see Koneracka, M. Ohaba, M., T. Sugimoto, T. Sawada, S. Sudo and T. Tanahashi, Oscillations of magnetic liquid columns Mellema, J., see de Gans, B.J. subject to random vibration Meunier, A., see Volkova, O. Ohaba, M., see Omura, N. Mezulis, A., see Blums, E. Ojha, V.N., see Pant, R.P. Mihalea, I., M. Morariu, M. Lita, I. Bibicu, A. Ercuta and D. Luca, Structural characterization of FeCrP-type Olaru, R., see Cotae, C. Olaru, R., see Calarasu, D. mesoscopic system Omura, N., K. Yamashita, T. Sawada and M. Ohaba, Miyazaki, T., see Fujita, T. Dynamic characteristics of a magnetic fluid column Monin, J., see Jamon, D. formed by magnetic field Morais, P.C., S.W. da Silva, M.A.G. Soler, M.H. Sousa Orlova, D.N., see Lebedev, V.T. and F.A. Tourinho, Raman study of ionic water- Orlova, D.N., see Lebedev, V.T. based copper and zinc ferrite magnetic fluids Ouakssim, A., see Roch, A. Morais, P.C., see Lacava, Z.G.M. Morariu, M., see Mihalca, I. Pant, R.P., V.K. Sankaranarayanan, V.N. Ojha and D.K. Morozov, K.I., Thermodiffusion in magnetic colloids Suri, Characterization of ferrofluid-polymer com- Mueller, R., see Ayoub, N.Y. posites on high T, superconductor Bi,Sr,Ca,Cu,O, Miiller, H.W., The dispersion of parametrically excited Pant, R.P., see Upadhyay, R.V. surface waves in viscous ferrofluids Papathanasiou, A.G. and A.G. Boudouvis, Three-dimen- Miiller, R., R. Hiergeist, H. Steinmetz, N. Ayoub, M. sional magnetohydrostatic instabilities of rotating Fujisaki and W. Schiippel, Barium hexaferrite ferrof- ferrofluid drops luids - preparation and physical properties Parekh, K., see Upadhyay, R.V. Muller, R.N., see Roch, A. Pavel, A., M. Trifan, LI. Bara, D.E. Creanga and C. Musil, C., see Turek, I. Cotae, Accumulation dynamics and some cytogeneti- cal tests at Chelidonium majus and Papaver som- Nakatani, I., see Lee, H.S. niferum callus under the magnetic liquid effect Nakatani, I., see Jeyadevan, B. Payet, B., F. Donatini and G. Noyel, Longitudinal mag- Nakatsuka, K., see Atarashi, T. neto-optical study of Brown relaxation in ferrofluids: Nakatsuka, K., see Zins, D. dynamic and transient methods. Application Nakatsuka, K., B. Jeyadevan, Y. Akagami, T. Torigoe Perzynski, R., see Hasmonay, E. and §. Asari, Visual observation of the effect of mag- Philipse, A.P., see de Gans, B.J. netic field on moving air and vapor bubbles in a mag- Philipse, A.P., see van Ewijk, G.A. netic fluid Philipse, A.P., see Donselaar, L.N. 494 Author index to volume 201 Pioch, L.L., see Zahn, M. 144 Rothert, A. and R. Richter, Experiments on the breakup Piso, M.I. and L. Vekas, Magnetic fluid composites and of a liquid bridge of magnetic fluid tools for microgravity experiments 410 Rusakov, V.V., see Raikher, Y.L. Piso, M.I., Applications of magnetic fluids for inertial Rylewicz, T., see Odenbach, S. sensors 380 Pogirnitskaya, S., see Bashtovoi, V. 300 Sala, F., Magnetic fluids effect upon growth processes in Ponsinet, V., see Spoliansky, D. 200 plants Popa, N.C., I. De Sabata, I. Anton, I. Potencz and L. Vekas, Sankaranarayanan, V.K., see Pant, R.P. Magnetic fluids in aerodynamic measuring devices 385 Sawada, T., see Kikura, H. Popa, N.C., A. Siblini and L. Jorat, Influence of the Sawada, T., see Ohaba, M. magnetic permeability of materials used for the con- Sawada, T., see Omura, N. struction of inductive transducers with magnetic fluid 398 Scholz, R., see Jordan, A. Popa, N.C., A. Siblini and L. Jorat, Gravitational electri- Schoppe, T., see Nethe, A. cal generator on magnetic fluid cushion 407 Schueppel, W., see Ayoub, N.Y. Potencz, I., see Vekas, L. 159 Schiippel, W., see Miiller, R. Potencz, I., see Popa, N.C. 385 Segal, V., D. Nattrass, K. Raj and D. Leonard, Acceler- Potencz, I., see Butnaru, G. 435 ated thermal aging of petroleum-based ferrofluids Potocova, I., M. Koneracka, P. Kopcansky, M. Timko, Semmler, W., see KOtitz, R. L. Toméo, J. Jadzyn and G. Czechowski, The influ- Shaposhnikova, G.A., see Buchin, V.A. ence of magnetic field on electric Fredericksz Shimada, K., see Yamaguchi, H. transition in 8CB-based ferronematic 163 Shimada, K., S. Kamiyama and M. Iwabuchi, Effect of a magnetic field on the performance of an energy Raikher, Y.L. and V.I. Stepanov, Transient field-induced conversion system using magnetic fluid birefringence in a ferronematic Sibilev, A.I., see Lebedev, V.T. Raikher, Y.L. and V.V. Rusakov, Dynamics of magneto- Sibilev, A.I., see Lebedev, V.T. orientational susceptibility in a viscoelastic magnetic Sibilev, A.I., see Lebedev, V.T. fluid Siblini, A., see Popa, N.C. Raj, K., see Segal, V. Siblini, A., see Popa, N.C. Ramchand, C.N., see Koneracka, M. Skjeltorp, A.T., see Fannin, P.C. Rasa, M., see Vekas, L. Socoliuc, V., see Jamon, D. Rasa, M., Improved formulas for magneto-optical effects Sofonea, V., see Jamon, D. in ferrofluids Sofonea, V., see Tulcan, E. Raga, M., see Jamon, D. Soler, M.A.G., see Morais, P.C. Rébula, C.A., see Lacava, Z.G.M. Sousa, M.H., see Morais, P.C. Rehberg, I., see Zeuner, A. Sousa, M.H., see Hasmonay, E. Rehberg, I., see Reimann, B. Sousa, M.H., see Lacava, Z.G.M. Rehberg, I., see Zeuner, A. Spoliansky, D., J. Ferre, J.-P. Jamet and V. Ponsinet, Reimann, B., T. Mahr, R. Richter and I. Rehberg, Stand- Relaxation of the magnetic field-induced birefrin- ing twin peaks due to non-monotonic dispersion of gence in ferrosmectics Faraday waves Srinivas, D., see Upadhyay, R.V. Reks, A., see Bashtovoi, V. Stahlmann, H.-D., see Nethe, A. Reks, A., see Bashtovoi, V. 328 StahImann, N.D., see Bashtovoi, V. Reks, A., see Bashtovoi, V. 332 Stanci, A. and V. Iusan, Magnetofluidic sensor for min- Revelskaya, L.G., see Lebedev, V.T. 136 eral quality control in preparation processes Richter, R., see Zeuner, A. 191] Stanci, A., see Hadgia, S. Richter, R., see Reimann, B. 303 Steinmetz, H., see Miiller, R. Richter, R., see Zeuner, A. 321 Stelina, J., see Turek, I. Richter, R., see Rothert, A. 324 Stepanov, V.I., see Raikher, Y.L. Richter, U., see Hiergeist, R. 420 Sudo, S., N. Wakamatsu, T. Ikohagi, H. Nishiyama, M. Rivoire, M., see Massart, R. 73 Ohaba and K. Katagiri, Magnetic field effects in the Rivoire, M., see Zins, D. 84 impact of a magnetic fluid drop Roch, A., P. Gillis, A.Q uakssim and R.N. Muller, Proton Sudo, S., see Ohaba, M. magnetic relaxation in superparamagnetic aqueous Sudo, S., T. Ikohagi, H. Nishiyama and K. Katagiri, colloids: a new tool for the investigation of ferrite Dynamic behavior of a magnetic fluid jet injected crystal anisotropy 77 from a vibrating nozzle Rosensweig, R.E., Theory for stabilization of magnetic Sugimoto, T., see Ohaba, M. colloid in liquid metal Sukhotsky, A., see Bashtovoi, V. Author index to volume 201 Suloeva, L., see Bashtovoi, V. 332 Vekas, L., see Popa, N.C. Suri, D.K., see Pant, R.P. 27 Vékas, L., see Piso, M.I. Suzuki, K., see Umehara, N. 372 Vincent, D., see Fannin, P.C. Suzuki, M., see Kato, K. 376 Volkova, O., S. Cutillas, P. Carletto, G. Bossis, A. Cebers and A. Meunier, Flow-induced structures in mag- Takeda, Y., see Kikura, H. 276 netorheological suspensions Tanahashi, T., see Ohaba, M. 293 Vroege, G.J., see van Ewijk, G.A. Tangthieng, C., B.A. Finlayson, J. Maulbetsch and T. Cader, Heat transfer enhancement in ferrofluids sub- Wagener, M. and B. Giinther, Sputtering on liquids jected to steady magnetic fields — a versatile process for the production of magnetic Terteac, D., see Butnaru, G. suspensions? Timko, M., see Potocova, I. Wagener, M., B. Giinther and E. Blums, Preparation of Timko, M., see Turek, I. oxidation resistant cobalt oil colloids Timko, M., see Koneracka, M. Wakamatsu, N., see Sudo, S. Tirziu, A., see Grabcev, B. Weitschies, W., see KOtitz, R. Tomasovicova, N., see Kopcansky, P. Wu, J.M., see Horng, H.E. Toméo, L., see Potocova, I. Wu, J.M., see Yang, H.C. Toméo, L., see Turek, I. Wu, J.M., see Jang, IJ. Tomco, L., see Kopcansky, P. Wu, K.T. and Y.D. Yao, Dynamic structure study of Tomosawa, K., see Matsuno, Y. Fe,O, ferrofluid emulsion in magnetic field Torigoe, T., see Nakatsuka, K. Wust, P., see Jordan, A. Torok, Gy., see Lebedev, V.T. Torok, Gy., see Lebedev, V.T. Yamaguchi, H., I. Kobori and N. Kobayashi, Numerical Torok, Gy., see Lebedev, V.T. study of flow state for a magnetic fluid heat transport Tourinho, F.A., see Morais, P.C. device Tourinho, F.A., see Hasmonay, E. Yamaguchi, H., I. Kobori, Y. Uehata and K. Shimada, Tourinho, F.A., see Lacava, Z.G.M. Natural convection of magnetic fluid in a rectangular Trahms, L., see K6titz, R. box Trifan, M., see Pavel, A. Yamashita, K., see Omura, N. Tulcan, E. and V. Sofonea, Morphology of cluster forma- Yang, H.C., see Horng, H.E. tion in magnetic fluids Yang, H.C., I.J. Jang, H.E. Horng, J.M. Wu, Y.C. Chiou Turek, I., J. Stelina, C. Musil, M. Timko, P. Kopéansky, and C.-Y. Hong, Behavior of the magnetic structures M. Koneracka and L. Toméo, The effect of self-dif- of the magnetic fluid film under tilted magnetic fields fraction in magnetic fluids Yang, H.C., see Jang, IJ. Turkov, V.A., see Naletova, V.A. Yang, S.Y., see Horng, H.E. Yao, Y.D., see Wu, K.T. Uehata, Y., see Yamaguchi, H. Yokota, Y., see Kamiyama, S. Ueno, K., see Kamiyama, S. Yushkov, A.V., see Zubarev, A. Yu. Ueno, K., T. Nishita and S. Kamiyama, Numerical simula- tion of deformed single bubbles rising in magnetic fluid Umehara, N. and K. Suzuki, Reduction of pull-off force Zahn, M. and L.L. Pioch, Ferrofluid flows in AC and with nanometer scale forming using magnetic fluid traveling wave magnetic fields with effective positive, and magnetic field zero or negative dynamic viscosity Umehara, N. and M. Kawauchi, Fundamental polishing Zeuner, A., R. Richter and I. Rehberg, On the consistency properties of frozen magnetic fluid grinding of the standard model for magnetoviscosity in an Umehara, N., see Kato, K. alternating magnetic field Upadhyay, R.V., see Massart, R. Zeuner, A., R. Richter and I. Rehberg, Weak periodic Upadhyay, R.V.,R.V. Mehta, K. Parekh, D. Srinivas and excitation of a magnetic fluid capillary flow R.P. Pant, Gd-substituted ferrite ferrofluid: a possible Zins, D., see Massart, R. candidate to enhance pyromagnetic coefficient Zins, D., K. Nakatsuka, F. Gendron and M. Rivoire, Upadhyay, R.V., see Koneracka, M. Evidence of reentrant behavior in nanoparticles of ferrite in ferrofluids Van Ewijk, G.A., G.J. Vroege and A.P. Philipse, Conve- Zubarev, A.Yu. and L.Yu. Iskakova, Nonlinear suscep- nient preparation methods for magnetic colloids tibilities and stochastic resonance in frozen dense Varga, L.K., see Lebedev, V.T. ferrocolloids Vékas, L., D. Bica, D. Gheorghe, I. Potencz and M. Rasa, Zubarev, A.Yu., see Ivanov, A.O. Concentration and composition dependence of the Zubarev, A.Yu., L.Yu. Iskakova and A.V. Yushkov, rheological behaviour of some magnetic fluids Dynamical properties of dense magnetic suspensions M ir Mma ELSEVIER Journal of Magnetism and Magnetic Materials 201 (1999) 496-497 www.elsevier.com/locate/jmmm Subject index to volume 201 AC susceptibility 113 Demagnetizing factor 110 Fluid vibration 306 Accumulation rate 446 Dense ferrocolloids 230 Frequency response 297 Acetone 14 Dense ferrofluids 226 Front capturing method 281 Actuator 423 Diamagnetism 113 Frozen magnetic fluid 364, 376 Aerodynamic measuring devices 385 Dielectric constant 394 g-jitter 293 Air bubbles 256 Dielectric fluids 70 Galerkin/finite element method 290 Amorphous powder 49 Dielectric tensor 170 Gas-phase synthesis 41 Anatomo-histological structure 435 Disk brake 401 Gravity 380 Anisotropy 178 Disordered magnetic spinel 84 Grinding wheel 364, 376 Anisotropy constant 119 Drops 300 Anisotropy energy 77 Drops and bubbles 324 Hardness 376 Dynamic viscosity 144 Harmonics 123 Bending 335 Dynamical susceptibility 226, 230 Heat pipes 256 Bifurcation 290 Heat transfer enhancement 252 Biocompatible material 431 Efficiency 357 Biology 440 Heat transport device 260 Electric Fredericksz transition 163 Hele-Shaw flow 339 Biomass 446 Electrical generator 407 Hexagonal structure 317 Biomedical applications 413 Electromagnetic device 252 High gradient magnetic separation 38 Birefringence 200 Elliptical polarization 215 HLB 14 Boundary integral equations 335 Emulsions 186 Hydro-electric power station 407 Brownian losses 420 Energy conversion 357 Hydrodynamics 346 Brownian relaxation 102 Energy dissipation 368 Hydrogen bond 105 Cancer 413 ESR 73 Hyperthermia 413 Chaetomium globosum Kunze: Fr 446 Feedback regulator 343 Chelidonium majus L 443 Immobilization 427 Ferrites 95, 98 Chemical stability 23 Impact phenomena 285 Ferrocolloids 248 Chemisorption 105 Impulse response 293 Ferrofluid 446 Citrate-based magnetic fluid 431 In vitro cultures 443 Ferrofluid droplet 335 Cluster formation 238 In vitro growth 435 Ferrofluid drops 290 Clusters 58 Inductive transducers 385, 398 Ferrofluids 18, 31, 34, 70, 84, 119, 123, 126, Cobalt colloids 18 Inertial sensors 410 133, 144, 170, 174, 186, 195, 242, 423 Colloids 31, 58 Instability 88, 343 Ferrogel 136 Complex magnetic fluids 211 Interaction 332 Ferromagnetic resonance 84, 116 Complex magnetic susceptibility 91 Interfacial instability 303, 350 Ferronematic liquid crystals 182 Complex permittivity 116 Interfacial oscillation 293 Ferronematics 163 Composites 27 Internal angular momentum 357 Ferrosmectics 200 Contrast agents 77, 449 Inverse ferrofluids 11 FIDAP 252 Cotton-Mouton rotation 215 Ionic ferrofluids 73 Film thickness discontinuity 346 Cryo-electron microscopy 58 Ionic magnetic fluid 431 Fine magnetic particles 95, 427 Ionic MF 62 Damages of FMs improving 435 Flat drops of magnetic fluid 300 Iron-dispersed magnetic fluids 7 Damper 368 Flow 276 Iron-nitride 23 DC remanence 119 Flow detection 353 Deformation of bubbles 281 Flow instability 260, 264 Jet breakup 306 0304-8853/99/$-see front matter © 1999 Elsevier Science B.V. All rights reserved. PII: $0304-8853(99)00440-0 Subject index to volume 201 Kinetics 222 Microgravity 410 SAR 413 Microgravity environment 297 SC 62 Labyrinthine structure 317 Microgravity research 149 Self-diffraction effect 167 Laminar flows 321 Morphology 238 SEM 27 Left ventricular assist device 423 Mossbauer spectroscopy 53 Sensors 380, 391, 394 Levitation 404 Shear thinning 155 Liquid column 297 Nanometer scale indentation 372 Shock absorber 368 Liquid crystals 14, 200 Nanoparticles 413 Silica 11, 31 Liquid metals 1 Natural convection 260, 264 Silica coating 7 Low boiling point alcohol 14 Néel and Brownian relaxation 91 Simulated hypogravity 435 Lubricant seal 361 Néel relaxation 102 Small angle neutron scattering 353 Neéel-losses 420 Soret coefficient 248, 268 Macrophage 431 Negative viscosity effect 191 Soret effect 167, 242, 268 Maghemite 31 Neutron inelastic scattering 80 Spin glass 84 Magnetic birefringence 182, 211 Neutron scattering 133, 136 Stability 290 Magnetic colloids 1, 31 Neutron small angle scattering 140 Static equilibrium 328 Magnetic convection 252 NMR imaging 449 Sterical stabilization 159 Magnetic drops 285 Non-linear oscillation 310 Stochastic resonance 230 Magnetic field 144, 300, 332, 372, 404 Nonlinear behaviour 123 Stripes 218 Magnetic fine particles 182, 211 Nonlinear dynamics 88 Structure ferrofluids 140 Magnetic fluid 14, 313 Nonlinear optics 88 Super critical flow 264 Magnetic fluid composites 410 Normal stress differences 149 Superparamagnetic colloids 77 Magnetic fluid drops 328 Nuclear magnetic resonance 77 Superparamagnetic particles 449 Magnetic fluid film 215 Numerical analysis 271, 357 Superparamagnetism 58 Magnetic fluids 23, 38, 58, 66, 88, 91, 95, 105, Numerical simulation 398 Surface profile 310 110, 113, 149, 155, 159, 167, 191, 204, 207, Ocean waves 407 Synthesis 18 222, 234, 256, 260, 264, 271, 276, 281, 285, Oil seal 361 297, 306, 332, 339, 346, 353, 357, 361, 368, Thermal aging 70 Oleic acid 31 372, 380, 385, 391, 398, 404, 407, 413, 440 Thermal decomposition 45 Optical switch 178 Magnetic force 332 Thermal diffusion 268 Ordered structures 313 Magnetic holes 11 Thermal diffusion (Soret effect) 88 Orthogonal fields 123 Magnetic interaction 328 Thermal diffusion column 242 Magnetic liquid column 293 Pair correlation 133 Thermo-hydrodynamic characteristics 357 Magnetic liquids 303, 321, 324, 350, 394, Papaver somniferum L 443 Thermodiffusion 248 401, 443 Particle concentration 159 Thermodiffusion column 268 Magnetic measurements 95 Pattern formation 88 Thermolysis 18 Magnetic nanoparticles 41, 45 Phase separation 66, 218, 222, 234 Thin films 313, 343, 346 Magnetic oil 18, 41 Plants 440 Tilted magnetic field 313 Magnetic ordering 80, 136, 186 Plasma jet 45 Toxicity 431 Magnetic particles 163 Polishing properties 364 Two-phase flow 271 Magnetic permeability 398 Ponderomotive interaction 332 Ultrafine particles 242 Magnetic properties 49 Primary cluster 62 Ultramicroscope 62 Magnetic resonance linewidth 126 Proteins and enzymes 427 Ultrasonic measurements 276 Magnetic susceptibility 98, 116 Pull-off force 372 Unsteady flow 271 Magnetic transition 80 Pyromagnetic coefficient 129 Magnetisation 129, 174 Vapor bubbles 256 Quality control 391 Magnetisation measurements 11 Vaporization 45 Magnetite 58 Raman spectroscopy 105 Vapour deposition 41 Magneto-dielectric effect 204 Rayleigh loops 420 Velocity profile 276 Magneto-optical birefringence 195 Relaxation 77 VERL 41 Magneto-optical effect 204 Relaxation time 207 Viscosity 38, 129, 207 Magneto-optical effects 170, 174 Resonance 91, 98 Viscosity measurements 321 Magneto-rheological suspension 49 Rheological properties 34, 159, 226, 368 Viscous fingering 339 Magnetodipolar interactions 218 Rheology 66, 149, 155 Viscous instability 350 Magnetoviscosity 191 Rising bubbles 281 Water-based MF 62 Magnets 328 Rosensweig-instability 310 Mesoscopic systems of particles 53 Rotating field 66, 218 X-ray microfocus 256 Microdrops 317 Rotating magnetic field 335 XRD 27, 53

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