ebook img

Journal of Magnetism and Magnetic Materials 2005: Vol 289 Index PDF

2005·3.2 MB·English
by  
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Journal of Magnetism and Magnetic Materials 2005: Vol 289 Index

Available online at www.sciencedirect.com JA, \ournal ot ecience @Poinecr magnetism and magnetic MMA wnateriais ELSEVIER Journal of Magnetism and Magnetic Materials 289 (2005) 534-541 www.elsevier.com/locate/jmmm Author index to volume 289 445 Ailiesei, O., see Dunca, S. Bee, A., see Saravia, D.C.A. 152 70 Albrecht, M., see Eberbeck, D. Bee, A., see Magalhaes, M. 385 268 Alexandrov, V., see Hennenberg, M. Bergemann, C., see Eberbeck, D. 435 118 Alves, C.R., see Sousa, E.C. Bica, D., see Vekas, L. 50 Alves, S.I., A. Bourdon and A.M. Figueiredo Neto, Bica, D., see Socoliuc, V. 177 Investigation of the Soret coefficient in magnetic Bica, D., see Kopéansky, P. 292 fluids using the Z-scan technique 285 Bily, A., see Zaichenko, A. 17 Amaro, E., see Gamarra, L.F. 439 Blums, E., New transport properties of ferroco- Andrade, S.S., D. Rabelo, V.K. Garg, A.C. Oliveira and lloids: magnetic Soret effect and thermomagne- P.C. Morais, Synthesis of magnetite nanoparticles in toosmosis 246 hydrophobic styrene—divinylbenzene copolymer tem- Blums, E., G. Kronkalns, M.M. Maiorov and A. plates 25 Mezulis, Thermoosmotic transfer of sterically stabi- Aquino, R., see Sousa, E.C. 118 lized ferrofluid particles in non-isothermal capillary Aquino, R., J.A. Gomes, F.A. Tourinho, E. Dubois, R. porous layer 275 Perzynski, G.J. da Silva and J. Depeyrot, Sm and Y Bolshakov, M., see Bolshakova, I. 108 radiolabeled magnetic fluids: magnetic and magneto- Bolshakova, I., see Zaichenko, A. 17 optical characterization 431 Bolshakova, I., M. Bolshakov, A. Zaichenko and A. Aritomi, M., see Kikura, H. 342 Egorov, The investigation of the magnetic fluid Aritomi, M., see Kikura, H. 392 stability using the devices with magnetic field Aurich, K., see Gléckl, G. 480 microsensors 108 Autenrieth, T., see Robert, A. 47 Bondarenko, E.A., see Chekanov, V.V. 155 Autenrieth, T., see Wagner, J. 54 B6nnemann, H., see Pop, L.M. 303 Ayrjan, E., see Kopéansky, P. 292 Bossis, G., see Bashtovoi, V. 376 Azevedo, R.B., see Eloi, M.T.A. 168 Bourdon, A., see Mériguet, G. 39 Azevedo, R.B., see Gravina, P.P. 448 Bourdon, A., see Alves, S.I. 285 Azevedo, R.B., see Santana, J.F.B. 452 Bourdon, A., see Magalhaes, M. 385 Azevedo, R.B., see Silva, L.P. 463 Bozhko, A. and T. Tynjalaé, Influence of gravitational Azevedo, R.B., see Sadeghiani, N. 466 sedimentation of magnetic particles on _ ferro- Azevedo, R.B., see Oliveira, D.M. 476 fluid convection in experiments and numerical simulations 281 Bracinik, J., see Kopcéansky, P. 97 Bracinik, J., see Kopéansky, P. 292 Bacri, J.C., see Janiaud, E. 215 Brinkmeier, V., see Gléckl, G. 480 Bacri, J.C., see Raikher, Y.L. 999 Brito, G.E.S., see Gamarra, L.F. 439 Bakuzis, A.F., see Skeff Neto, K. 129 Brunke, O., S. Odenbach, C. Fritsche, I. Hilger and Bakuzis, A.F., see Gongalves, G.R.R. 142 W.A. Kaiser, Determination of magnetic particle Bakuzis, A.F., see Castro, L.L. 230 distribution in biomedical applications by X-ray Bakuzis, A.F., see Gravina, P.P. 448 microtomography 428 Barbosa, L.S., see Sadeghiani, N. 466 Bulte, J.W.M., Magnetic nanoparticles as markers for Bashtovoi, V., O. Lavrova, T. Mitkova, V. Polevikov cellular MR imaging 423 and L. Tobiska, Flow and energy dissipation in a magnetic fluid drop around a _ permanent magnet 207 Bashtovoi, V., M. Kovalev and A. Reks, Instabilities of Cabuil, V., see Ramaye, Y. 28 bubbles and droplets flows in magnetic fluids 350 Calugaru, G., see Creanga, D. 81 Bashtovoi, V., G. Bossis, P. Kuzhir and A. Reks, Campos, A.F.C., F.A. Tourinho, G.J. da Silva and J. Magnetic field effect on capillary rise of magnetic Depeyrot, Calculation of the pair potential interac- fluids 376 tion in electric double-layered magnetic fluids: a Bashtovoi, V., M. Kovalev and A. Reks, Separation of quantitative analysis of the pH-dependent phase bubbles from solid surfaces in magnetic fluids 382 diagram 171 doi: 10.1016/S0304-8853(05)00233-7 Author index to volume 289 535 Castro, L.L., M.F. da Silva, A.F. Bakuzis and R. Dutra, H., see Ferreira, J. 442 Miotto, Mono-disperse ferrofluids clusterization: a Monte Carlo study 230 Cebers, A., Dynamics of elongated magnetic droplets Eberbeck, D., V. Janke, S. Hartwig, U. Heyen, D. and elastic rods in magnetic field 335 Schiiler, M. Albrecht and L. Trahms, Blocking of Cebers, A., see Janiaud, E. 215 magnetic moments of magnetosomes measured by Cebers, A., see Tatulchenkov, A. 373 magnetorelaxometry and direct observation by Cernicchiaro, G., see Ferreira, J. 442 magnetic force microscopy 70 Charles, S.W., see Fannin, P.C. 133 Eberbeck, D., C. Bergemann, S. Hartwig, U. Steinhoff Charles, S.W., see Giannitsis, A.T. 165 and L. Trahms, Binding kinetics of magnetic Chekanov, V.V., P.M. Iljuch, N.V. Kandaurova and nanoparticles on latex beads and yeast cells studied E.A. Bondarenko, Autowaves in near-surface layer by magnetorelaxometry 435 of magnetic fluid 155 Egorov, A., see Bolshakova, I. 108 Chen, C.-Y. and H.-J. Wu, Fingering instabilities Elborai, S., see Rosensweig, R.E. 192 of a miscible magnetic droplet on a rotating Hele— Elborai, S., see Rhodes, S. 353 Shaw cell 339 Elfimova, E.A., Fractal aggregates in magnetic fluids 219 Chen, C.-Y., H.-J. Wu and L. Hsu, Numerical simula- Eloi, M.T.A., R.B. Azevedo, E.C.D. Lima, A.C.M. tions of labyrinthine instabilities on a _ miscible Pimenta and P.C. Morais, Birefringence and trans- elliptical magnetic droplet mission electron microscopy of maghemite-based Cheng, Y., see Liu, T. biocompatible magnetic fluids 168 Cotae, V. and I. Creanga, LHC II system sensitivity to Elias, F., see Janiaud, E. 215 magnetic fluids Esquivel, D.M.S., see Ferreira, J. 442 Creanga, D. and G. Calugaru, Physical investigations of a ferrofluid based on hydrocarbons Creanga, D.-E., see Dunca, S. Fannin, P.C., C.N. Marin, I. Malaescu and A.T. Creanga, D.-E., see Poiata, A. Giannitsis, Microwave absorption of composite Creanga, D.-E., see Pavel, A. magnetic fluids 78 Creanga, D.-E., see Manoliu, A. Fannin, P.C., Y.P. Kalmykov and S.W. Charles, Creanga, I., see Cotae, V. Investigation of subsidiary loss-peaks in the fre- Cunha, F.R. and Y.D. Sobral, Asymptotic solution quency dependent susceptibility profiles of magnetic for pressure-driven flows of magnetic fluids in fluids 133 pipes Fannin, P.C., B.K.P. Scaife, A.T. Giannitsis and C. Mac Cunha, F.R., see Sobral, Y.D. Oireachtaigh, High frequency ferromagnetic reso- Cunha, F.R., see Ramos, D.M. nance measurements in magnetic fluids 159 Cunha, F.R., see Sobral, Y.D. Fannin, P.C., 1. Malaescu and C.N. Marin, The effective Czechowski, G., see Kopéansky, P. anisotropy constant of particles within magnetic fluids as measured by magnetic resonance 162 Fannin, P.C., see Giannitsis, A.T. 165 da Silva, G.J., see Campos, A.F.C. Fernandes, P.R.G., H. Mukai and I.M. Laczkowski, da Silva, G.J., see Aquino, R. Magneto-optical effect in lyotropic liquid crystal da Silva, M.F., see Castro, L.L. doped with ferrofluid 115 da Silva, S.W., see Pedroza, R.C. Ferreira, J., G. Cernicchiaro, M. Winklhofer, H. Dutra, da Silva, S.W., see Santana, J.F.B. P.S. de Oliveira, D.M. S. Esquivel and E. Wajnberg, de Oliveira, P.S., see Ferreira, J. Comparative magnetic measurements on social Demouchy, G., see Mériguet, G. insects 442 Depeyrot, J., see Sousa, E.C. Figueiredo Neto, A.M., see Alves, S.1. 285 Depeyrot, J., see Campos, A.F.C. Figueiredo Neto, A.M., see Magalhaes, M. 385 Depeyrot, J., see Gomes, J.A. Figueiredo, J.M.A., see Licinio, P. 18] Depeyrot, J., see Aquino, R. Fischer, B., B. Huke, M. Liicke and R. Hempelmann, Desaive, T., see Hennenberg, M. Brownian relaxation of magnetic colloids 74 Dikansky, Y.I. and O.A. Nechaeva, Electrohydrodyna- Fontoura Rodrigues, J.L.A., see Ramos, D.M. 238 mical instability of microdrops shapes in a magnetic Fritsche, C., see Brunke, O. 428 fluid Dikansky, Y.I., see Veguera, J.G. Drofenik, M., see Makovec, D. Dubois, E., see Mériguet, G. Gaind, A.P., see Ganguly, R. 331 Dubois, E., see Aquino, R. Gamarra, L.F., G.E.S. Brito, W.M. Pontuschka, E. Dunca, S., D.-E. Creanga, O. Ai\jtliesei and Amaro, A.H.C. Parma and G.F. Goya, Biocompa- E. Nimitan, Microorganisms growth with magnetic tible superparamagnetic iron oxide nanoparticles fluids used for contrast agents: a structural and magnetic Dupuis, V., see Meriguet, G. study 439 536 Author index to volume 289 Ganguly, R., A.P. Gaind, S. Sen and I.K. Puri, Hergt, R., see Miiller, R. 13 Analyzing ferrofluid transport for magnetic drug Herreman, W., P. Molho and S. Neveu, Magnetic field targeting 331 effects on viscous fingering of a ferrofluid in a radial Garg, V.K., see Andrade, S.S. 25 Hele—Shaw cell 356 Gawalek, W., see Miiller, R. 13 Hess, S., see Ilg, P. 325 Giannitsis, A.T., see Fannin, P.C. 78 Heyen, U., see Eberbeck, D. 70 Giannitsis, A.T., see Fannin, P.C. 159 Hilger, I., see Brunke, O. 428 Giannitsis, A.T., P.C. Fannin and S.W. Charles, Non- Hirashima, O., see Kikura, H. 392 linear effects in magnetic fluids 165 Hnatic, M., see Kopéansky, P. 292 Gloéckl, G., V. Brinkmeier, K. Aurich, E. Romanus, Holm, C., see Huang, J.P. 234 P. Weber and W. Weitschies, Development Hong, C.-Y., Y.H. Ke, H.E. Horng, S.Y. Yang and of a liquid phase immunoassay by time-dependent H.C. Yang, Thermal activated variation in measurements of the transient magneto-optical the ordered structures in magnetic fluids birefringence using functionalized magnetic films nanoparticles 480 Horng, H.E., see Hong, C.-Y. Gomes, J.A., M.H. Sousa, F.A. Tourinho, J. Mestnik- Hsu, L., see Chen, C.-Y. 364 Filho, R. Itri and J. Depeyrot, Rietveld structure Huang, J.P., Z.W. Wang and C. Holm, Structure and refinement of the cation distribution in ferrite fine magnetic properties of mono- and _bi-dispersed particles studied by X-ray powder diffraction 184 ferrofluids as revealed by simulations Gomes, J.A., see Aquino, R. 431 Huang, X.Y., see Nguyen, N.T. Gongalves, G.R.R., A.F. Bakuzis, K. Skeff Neto, F. Huke, B. and M. Liicke, Roll, square, and cross-roll Pelegrini and P.C. Morais, Magnetic resonance convection in ferrofluids investigation of the particle—particle equilibrium Huke, B., see Fischer, B. distance within small agglomerates in magnetic fluids 142 Gongalves, G.R.R., see Skeff Neto, K. 129 Gongalves, M., see Silva, A.J. 295 Iig, P., M. Kroger and S. Hess, Structure and rheology Goya, G.F., see Sousa, E.C. 118 of model-ferrofluids under shear flow 325 Goya, G.F., see Gamarra, L.F. 439 Iljuch, P.M., see Chekanov, V.V. 155 Gravina, P.P., A.F. Bakuzis, K. Skeff Neto, R.B. Ishimoto, J. and S. Kamiyama, Numerical study of Azevedo and P.C. Morais, Investigation of the pH cavitating flow of magnetic fluid in a_ vertical effect on the stability of biocompatible magnetic converging—diverging nozzle 260 fluids using time-dependent birefringence measure- Itri, R., see Gomes, J.A. 184 448 ments Ivanov, A., see Mendelev, V. 211 47 Griibel, G., see Robert, A. Ivanov, A., see Kuznetsova, O. 226 54 Griibel, G., see Wagner, J. 452 Guedes, M.H., see Santana, J.F.B. 463 Guedes, M.H.A.., see Silva, L.P. Gutman, F., see Rinaldi, C. 307 Jackson, D.P., Theory, experiment, and simulations of a symmetric arrangement of quasi-two-dimensional magnetic fluid drops Jadzyn, J., see Kopéansky, P. Hartl, W., see Robert, A. 47 Janiaud, E., J.C. Bacri, A. Cebers and F. Elias, Magnetic Hartl, W., see Wagner, J. 54 forces in 2D foams Hartwig, A., see Kroell, M. 21 Janke, V., see Eberbeck, D. Hartwig, S., see Eberbeck, D. 70 Jansen, A.G.M., see Kopéansky, P. Hartwig, S., see Eberbeck, D. 435 Jeyadevan, B., see Sato, K. He, X., see Rinaldi, C. 307 Jeyadevan, B., H. Koganezawa and K. Nakatsuka, He, X., see Li, D. 399 Performance evaluation of citric ion-stabilized mag- He, X., see Li, D. 407 netic fluid heat pipe He, X., see Li, D. 419 Jurikova, A., see Kopéansky, P. Hee Kim, E., H. Sook Lee, B. Kook Kwak and B.-K. Kim, Synthesis of ferrofluid with magnetic nanopar- ticles by sonochemical method for MRI contrast agent 328 Kaiser, W.A., see Brunke, O. Heinemann, A. and A. Wiedenmann, Insight into the Kalmykov, Y.P., see Fannin, P.C. formation of partially ordered structures in Co-based Kamiyama, S., see Shimada, K. ferrofluids Kamiyama, S., see Ishimoto, J. Heinemann, A., see Wiedenmann, A. Kandaurova, N.V., see Chekanov, V.V. Hempelmann, R., see Fischer, B. Kanno, H., see Shimada, K. Hennenberg, M., B. Weyssow, S. Slavtchev, V. Alexandrov Kantorovich, S.S., Chain aggregate structure in poly- and T. Desaive, Rayleigh-Marangoni-Benard instabil- disperse ferrofluids: different applications ity of a ferrofluid layer in a vertical magnetic field 268 Ke, Y.H., see Hong, C.-Y. Author index to volume 289 537 Kikura, H., M. Aritomi and Y. Takeda, Velocity Lan, H., see Li, D. 399 measurement on Taylor—Couette flow of a magnetic Lan, H., see Li, D. 407 fluid with small aspect ratio Lan, H., see Li, D. 419 Kikura, H., J. Matsushita, O. Hirashima, M. Aritomi Lavrova, O., see Bashtovoi, V. 207 and I. Nakatani, Flow visualization and particle size Lee, S.-H., see Rosensweig, R.E. 192 determination of primary clusters in a water-based Lee, S.-H., see Rhodes, S. 353 magnetic fluid Li, D., H. Xu, X. He and H. Lan, Theoretical and Kim, B.-K., see Hee Kim, E. experimental study on the magnetic fluid seal of Koganezawa, H., see Jeyadevan, B. reciprocating shaft 399 Koneracka, M., see Kopéansky, P. Li, D., H. Xu, X. He and H. Lan, Mechanism of Koneracka, M., see Kopéansky, P. magnetic liquid flowing in the magnetic liquid seal Koneracka, M., see Kopéansky, P. gap of reciprocating shaft 407 Kook Kwak, B., see Hee Kim, E. Li, D., H. Xu, X. He and H. Lan, Study on the magnetic Kopéansky, P., M. Hnati¢, M. RepaSan, I. Potocova, M. fluid sealing for dry Roots pump 419 Timko, I. Turek, J. Stelina, C. Musil, J. Bracinik, E. Li, Z. and K. Raj, Effect of vacuum level on evaporation Ayrjan, L. Vekas and D. Bica, The light-induced rate of magnetic fluids 43 structuralization in magnetic fluids with negative Licinio, P., see Teixeira, A.V. 126 Soret constant 292 Licinio, P., A.V. Teixeira and J.M.A. Figueiredo, Non- Kopéansky, P., I. Potocova, M. Koneracka, M. Timko, linear dielectric response of ferrofluids under mag- A.G.M. Jansen, J. Jadzyn and G. Czechowski, The netic field 181 anchoring of nematic molecules on magnetic parti- Lima, E.C.D., see Eloi, M.T.A. 168 cles in some types of ferronematics 101 Lima, E.C.D., see Oliveira, D.M. 476 Kopéansky, P., M. Timko, I. Potocova, M. Koneracka, Liu, T., Y. Cheng and Z. Yang, Design optimization of A. Jurikova, N. Tomasovitova, J. Stelina, C. Musil seal structure for sealing liquid by magnetic fluids 411 17 and J. Bracinik, The determination of the hydro- Lobaz, V., see Zaichenko, A. 74 dynamic diameter of magnetic particles using FRS Liicke, M., see Fischer, B. 264 experiment 97 Liicke, M., see Huke, B. Kopéansky, P., L. Toméo, K. Marton, M. Koneracka, M. Timko and I. Pototova, The DC dielectric breakdown strength of magnetic fluids based on Mac Ojireachtaigh, C., see Fannin, P.C. 159 transformer oil 415 Macaroff, P.P., see Oliveira, D.M. 476 KoSak, A., see Makovec, D. 32 Magalhaes, M., A.M. Figueiredo Neto, A. Bee, D. Koser, H., see Mao, L. 199 Talbot and A. Bourdon, Wetting of glass surface Kovalev, M., see Bashtovoi, V. 350 covered with Teflon by ferrofluid as a function of Kovalev, M., see Bashtovoi, V. 382 concentration and size of grains, and pH of the Krakov, M.S. and I.V. Nikiforov, Thermomagnetic solution 385 convection in a porous enclosure in the presence of Maiorov, M.M., see Blums, E. 275 outer uniform magnetic field 278 Makovec, D., A. Kosak, A. Znidarsié and M. Drofenik, Krakov, M.S., I.V. Nikiforov and A.G. Reks, Influence The synthesis of spinel-ferrite nanoparticles using of the uniform magnetic field on natural convection precipitation in microemulsions for ferrofluid appli- in cubic enclosure: experiment and numerical cations 32 simulation 272 Malaescu, I., see Fannin, P.C. 78 Kroell, M., M. Pridoehl, G. Zimmermann, L. Pop, S. Malaescu, I., see Fannin, P.C. 162 Odenbach and A. Hartwig, Magnetic and rheological Manoliu, A., L. Oprica and D.-E. Creanga, Ferrofluid characterization of novel ferrofluids 21 and cellulolytic fungi 473 Kroéger, M., see Ilg, P. 325 Mao, L. and H. Koser, Ferrohydrodynamic pumping in Kronkalns, G., see Blums, E. 275 spatially traveling sinusoidally time-varying mag- Kuckelhaus, S., see Silva, L.P. 463 netic fields 199 Kuwahara, T. and H. Yamaguchi, Void fraction Marin, C.N., see Fannin, P.C. 78 measurement in magnetic fluid 403 Marin, C.N., see Fannin, P.C. 162 Kuzhir, P., see Bashtovoi, V. 376 Marinica, O., see Vekas, L. 50 Kuznetsova, O. and A. Ivanov, Spontaneous orienta- Marton, K., see Kopéansky, P. 415 tional ordering in magnetic fluids 226 Matoussevitch, N., see Pop, L.M. 303 Kvitantsev, A.S., see Naletova, V.A. 250 Matsushita, J., see Kikura, H. 392 Matthies, G. and L. Tobiska, Numerical simulation of normal-field instability in the static and dynamic Lacava, Z.G.M., see Santana, J.F.B. 452 case 346 Lacava, Z.G.M., see Silva, L.P. 463 Mehta, R.V., R.V. Upadhyay, R. Patel and P. Trivedi, Lacava, Z.G.M., see Sadeghiani, N. 466 Magnetooptical effects in magnetic fluid containing Lacava, Z.G.M., see Oliveira, D.M. 476 large aggregates 36 Laczkowski, I.M., see Fernandes, P.R.G. 115 Mehta, R.V., see Parekh, K. 311 538 Author index to volume 289 Mendelev, V. and A. Ivanov, Magnetic properties of Nguyen, N.T., Z.G. Wu, X.Y. Huang and C.-Y. Wen, ferrofluids: an influence of chain aggregates 211 The application of PIV technique in the study of Meriguet, G., E. Dubois, A. Bourdon, G. Demouchy, magnetic flows in a micro-channel 396 V. Dupuis and R. Perzynski, Forced Rayleigh Nikiforov, I.V., see Krakov, M.S. 272 scattering experiments in concentrated magnetic Nikiforov, I.V., see Krakov, M.S. 278 fluids: effect of interparticle interactions on the Nimitan, E., see Dunca, S. 445 diffusion coefficient 39 Nishiyama, H., see Sudo, S. 321 Mestnik-Filho, J., see Gomes, J.A. 184 Novak, M.A., see Morais, P.C. 174 Mezulis, A., see Blums, E. 275 Nunes, W.C., see Morais, P.C. 174 Miotto, R., see Castro, L.L. 230 Miranda, J.A., see Oliveira, R.M. 360 Miranda, J.A., see Scherer, C. 484 Odenbach, S. and H.W. Miiller, On the microscopic Mitina, N., see Zaichenko, A. 17 interpretation of the coupling of the symmetric Mitkova, T., see Bashtovoi, V. 207 velocity gradient to the magnetization relaxation Molho, P., see Herreman, W. 356 Odenbach, S. and T. Vélker, Thermal convection in a Morais, P.C., J.G. Santos, L.B. Silveira, W.C. Nunes, ferrofluid supported by thermodiffusion J.P. Sinnecker and M.A. Novak, Magnetic investiga- Odenbach, S., see Kroell, M. tion of zero-field-cooled dextran-coated magnetite- Odenbach, S., see Volker, T. based magnetic fluid 174 Odenbach, S., see Pop, L.M. Morais, P.C., see Andrade, S.S. 25 Odenbach, S., see Brunke, O. Morais, P.C., see Pelegrini, F. 84 Oliveira, A.C., see Andrade, S.S. Morais, P.C., see Skeff Neto, K. 129 Oliveira, D.M., P.P. Macaroff, K.F. Ribeiro, Z.G.M. Morais, P.C., see Silva, O. 136 Lacava, R.B. Azevedo, E.C.D. Lima, P.C. Morais Morais, P.C., see Pedroza, R.C. 139 and A.C. Tedesco, Studies of zinc phthalocyanine; Morais, P.C., see Gongalves, G.R.R. 142 magnetic fluid complex as a bifunctional agent for Morais, P.C., see Pereira, A.R. 146 cancer treatment 476 Morais, P.C., see Eloi, M.T.A. 168 Oliveira, R.M. and J.A. Miranda, Magnetic fluid in a Morais, P.C., see Gravina, P.P. 448 time-dependent gap Hele—Shaw cell 360 Morais, P.C., see Santana, J.F.B. 452 Oprica, L., see Manoliu, A. 473 Morais, P.C., see Silva, L.P. 463 Oshiama, S., see Yamane, R. 389 Morais, P.C., see Sadeghiani, N. 466 Morais, P.C., see Oliveira, D.M. 476 Motozawa, M. and T. Sawada, Influence of magnetic Padalka, V.V., see Yerin, C.V. 105 field on ultrasonic propagation velocity in magnetic Parekh, K., R. Patel, R.V. Upadhyay and R.V. Mehta, fluids 66 Field-induced diffraction patterns in a magneto- Mukai, H., see Fernandes, P.R.G. 115 rheological suspension 311 Miiller, R., R. Hergt, M. Zeisberger and W. Gawalek, Park, M.-K., see Yamane, R. 389 Preparation of magnetic nanoparticles with large Parma, A.H.C., see Gamarra, L.F. 439 specific loss power for heating applications 13 Patel, R., see Mehta, R.V. 36 Miiller, H.W., see Odenbach, S. 242 Patel, R., see Parekh, K. 311 Musil, C., see Kopéansky, P. 97 Pavel, A. and D.-E. Creanga, Chromosomal Musil, C., see Kopéansky, P. 292 aberrations in plants under magnetic fluid influence 469 Pedroza, R.C., S.W. da Silva, M.A.G. Soler, P.P.C. Nakagawa, A., see Sudo, S. 321 Sartoratto, D.R. Rezende and P.C. Morais, Raman Nakatani, I., see Kikura, H. 392 study of nanoparticle-template interaction in a Nakatsuka, K., see Jeyadevan, B. 253 CoFe,0,4/Si0,-based nanocomposite prepared by Naletova, V.A. and A.S. Kvitantsev, Thermomagnetic sol-gel method 139 force acting on a spheroidal body in a magnetic Pelegrini, F., A.R. Pereira and P.C. Morais, Ferromag- fluid 250 netic resonance line of ferrite ferrofluids at high Naletova, V.A., V.A. Turkov, V.V. Sokolov and A.N. microwave power 84 Tyatyuskin, The interaction of the particles of Pelegrini, F., see Skeff Neto, K. 129 magnetizable suspensions with a_ wall (wall- Pelegrini, F., see Goncalves, G.R.R. 142 adjacent effect) in uniform electric and magnetic Pelegrini, F., see Pereira, A.R. 146 fields 367 Pereira, A.R., F. Pelegrini and P.C. Morais, Magnetic Naletova, V.A., V.A. Turkov and A.N. Tyatyushkin, resonance investigation of monodisperse oleoylsar- Spherical body in a magnetic fluid in uniform electric cosine-coated magnetic fluid 146 and magnetic fields 370 Pereira, A.R., see Pelegrini, F. 84 Nechaeva, O.A., see Dikansky, Y.I. 90 Perez, J., see Rhodes, S. 353 Neveu, S., see Ramaye, Y. 28 Perzynski, R., see Mériguet, G. 39 Neveu, S., see Herreman, W. 356 Perzynski, R., see Raikher, Y.L. 9799 re Author index to volume 289 539 Perzynski, R., see Aquino, R. 431 Sadeghiani, N., L.S. Barbosa, L.P. Silva, R.B. Azevedo, Pimenta, A.C.M., see Eloi, M.T.A. 168 P.C. Morais and Z.G.M. Lacava, Genotoxicity and Poiata, A., A. Vlahovici and D.-E. Creanga, Ferrofluid inflammatory investigation in mice treated with effect on Pseudomonas pyoverdine 455 magnetite nanoparticles surface coated with poly- Polevikov, V. and L. Tobiska, Instability of magnetic aspartic acid 466 fluid in a narrow gap between plates 379 Sakatani, K., see Shuchi, S. 257 Polevikov, V., see Bashtovoi, V. 207 Santana, J.F.B., M.A.G. Soler, S.W. da Silva, M.H. Pontuschka, W.M., see Gamarra, L.F. 439 Guedes, Z.G.M. Lacava, R.B. Azevedo and P.C. Pop, L., see Kroell, M. Morais, Investigation of the interaction between Pop, L.M., S. Odenbach, A. Wiedenmann, N. Matous- magnetic nanoparticles surface-coated with carbox- sevitch and H. Bénnemann, Microstructure and ymethyldextran and blood cells using Raman spec- rheology of ferrofluids troscopy Potocova, I., see Koptansky, P. Santos, J.G., see Morais, P.C. Potocova, I., see Kopéansky, P. Saravia, D.C.A., A. Bee and S.M. Shibli, Blocking Potocova, I., see Koptansky, P. phenomena studies on ferronematics Potocova, I., see Kopéansky, P. Sartoratto, P.P.C., see Pedroza, R.C. Pridoehl, M., see Kroell, M. Sato, K., B. Jeyadevan and K. Tohji, Prepa- Puri, I.K., see Ganguly, R. ration and properties of ferromagnetic FePt dispersion Sawada, T., see Motozawa, M. Scaife, B.K.P., see Fannin, P.C. Rabelo, D., see Andrade, S.S. Scherer, C. and J.A. Miranda, Introduction to the Raikher, Y.L. and O.V. Stolbov, Magnetodeformational magnetic fluids bibliography effect in ferrogel objects Scherer, C., Computer simulation of magnetorheological Raikher, Y.L., V.I. Stepanov, J.C. Bacri and R. transition on a ferrofluid emulsion Perzynski, Orientational dynamics in magnetic fluids Scherer, C., Magnetic Fluids Bibliography (2001- under strong coupling of external and internal 2004) relaxations Schmidt, A.M., Induction heating of novel thermore- Raj, K., see Li, Z. sponsive ferrofluids Ramaye, Y., S. Neveu and V. Cabuil, Ferrofluids from Schiiler, D., see Eberbeck, D. prism-like nanoparticles Sen, S., see Ganguly, R. Ramos, D.M., F.R. Cunha, Y.D. Sobral and J.L.A. Shevchuk, O., see Zaichenko, A. Fontoura Rodrigues, Computer simulations of Shibli, S.M., see Saravia, D.C.A. magnetic fluids in laminar pipe flows Shibli, S.M., see Silva, A.J. Rasa, M., see Vekas, L. Shimada, K., S. Shuchi, H. Kanno, Y. Wu and S. Rechenberg, H.R., see Sousa, E.C. Kamiyama, Magnetic cluster and its applications Reks, A., see Bashtovoi, V. Shimada, K., see Sudo, S. Reks, A., see Bashtovoi, V. Shuchi, S., see Shimada, K. Reks, A., see Bashtovoi, V. Shuchi, S., K. Sakatani and H. Yamaguchi, An Reks, A.G., see Krakov, M.S. application of a binary mixture of magnetic fluid Repasan, M., see Kopéansky, P. for heat transport devices 257 Rezende, D.R., see Pedroza, R.C. Silva, A.J., M. Gongalves and S.M. Shibli, Thermo- Rhodes, S., J. Perez, S. Elborai, S.-H. Lee and M. Zahn, diffusion study in ferrofluids through collinear Ferrofluid spiral formations and _ continuous- mirage effect 295 to-discrete phase transitions under simultaneously Silva, L.P., S. Kuckelhaus, M.H.A. Guedes, Z.G.M. applied DC axial and AC in-plane rotating magnetic Lacava, A.C. Tedesco, P.C. Morais and R.B. fields 353 Azevedo, Kinetic of magnetic nanoparticles uptake Ribeiro, K.F., see Oliveira, D.M. 476 evaluated by morphometry of mice peritoneal cells 463 Rinaldi, C., F. Gutman, X. He, A.D. Rosenthal and M. Silva, L.P., see Sadeghiani, N. 466 Zahn, Torque measurements on ferrofluid cylinders Silva, O. and P.C. Morais, Investigation of anisotropy in in rotating magnetic fields 307 cadmium ferrite-based ionic magnetic fluid using 136 Robert, A., J. Wagner, T. Autenrieth, W. Hartl and G. magnetic resonance 174 Griibel, Coherent X-rays as a new probe for the Silveira, L.B., see Morais, P.C. 174 investigation of the dynamics of opaque colloidal Sinnecker, J.P., see Morais, P.C. suspensions 47 Skeff Neto, K., A.F. Bakuzis, G.R.R. Gongalves, F. Robert, A., see Wagner, J. 54 Pelegrini and P.C. Morais, Evidence of phase Romanus, E., see Gléckl, G. 480 separation in magnetic colloids using magnetic Rosensweig, R.E., S. Elborai, S.-H. Lee and M. Zahn, resonance 129 Ferrofluid meniscus in a horizontal or vertical Skeff Neto, K., see Gongalves, G.R.R. 142 magnetic field 192 Skeff Neto, K., see Gravina, P.P. 448 Rosenthal, A.D., see Rinaldi, C. 307 Slavtchev, S., see Hennenberg, M. 268 540 Author index to volume 289 Sobral, Y.D. and F.R. Cunha, Hierarchy of concentra- Tyatyuskin, A.N., see Naletova, V.A. tion waves in magnetic fluidized beds 111 Tynjala, T., see Bozhko, A. Sobral, Y.D. and F.R. Cunha, Drift velocity and deformation of polarized drops in magnetic fields 318 Upadhyay, R.V., see Mehta, R.V. Sobral, Y.D., see Ramos, D.M. 238 Upadhyay, R.V., see Parekh, K. Sobral, Y.D., see Cunha, F.R. 314 Socoliuc, V. and D. Bica, The influence of the Neéel rotation on the magnetic induced dichroism in Veguera, J.G. and Y.I. Dikansky, Periodical structure in magnetic fluids 177 a magnetic fluid under the action of an electric field Socoliuc, V., see Vekas, L. 50 and with a shear flow 87 Sokolov, V.V., see Naletova, V.A. 367 Vekas, L., D. Bica, O. Marinica, M. Rasa, V. Socoliuc Soler, M.A.G., see Pedroza, R.C. 139 and F.D. Stoian, Concentrated magnetic fluids on Soler, M.A.G., see Santana, J.F.B. 452 water and short chain length organic carriers 50 Sook Lee, H., see Hee Kim, E. 328 Vekas, L., see Kopéansky, P. 292 Sousa, E.C., C.R. Alves, R. Aquino, M.H. Sousa, G.F. Vlahovici, A., see Poiata, A. 455 Goya, H.R. Rechenberg, F.A. Tourinho and J. Vélker, T. and S. Odenbach, Thermodiffusion in Depeyrot, Experimental evidence of surface effects magnetic fluids 289 in the magnetic dynamics behavior of ferrite Volker, T., see Odenbach, S. 122 nanoparticles Sousa, M.H., see Sousa, E.C. Sousa, M.H., see Gomes, J.A. Steinhoff, U., see Eberbeck, D. Wagner, J., T. Autenrieth, A. Robert, W. Hartl and G. Stelina, J., see Kopéansky, P. Griibel, Structure and dynamics of complex liquids Stelina, J., see Kopéansky, P. with magnetic dipole-dipole interactions by means of Stepanov, V.I., see Raikher, Y.L. static and dynamic X-ray scattering Stoian, F.D., see Vekas, L. Wagner, J., see Robert, A. Stolbov, O.V., see Raikher, Y.L. Wajnberg, E., see Ferreira, J. Su, W.-P., see Wen, C.-Y. Wang, Z.W., see Huang, J.P. Sudo, S., A. Nakagawa, K. Shimada and H. Nishiyama, Weber, P., see Glock], G. Shape response of functional fluid drops in alternat- Weitschies, W., see Gléckl, G. ing magnetic fields Wen, C.-Y. and W.-P. Su, Natural convection of Takeda, Y., see Kikura, H. magnetic fluid in a rectangular Hele-Shaw cell Talbot, D., see Magalhaes, M. Wen, C.-Y., see Nguyen, N.T. Tatulchenkov, A. and A. Cebers, Shapes of a gas bubble Weyssow, B., see Hennenberg, M. rising in the vertical Hele-Shaw cell with magnetic liquid Wiedenmann, A. and A. Heinemann, Field-induced Tedesco, A.C., see Silva, L.P. ordering phenomena in ferrofluids observed by Tedesco, A.C., see Oliveira, D.M. small-angle neutron scattering Teixeira, A.V. and P. Licinio, Local deformations of Wiedenmann, A., see Heinemann, A. ferrogels induced by uniform magnetic fields Wiedenmann, A., see Pop, L.M. Teixeira, A.V., see Licinio, P. Winklhofer, M., see Ferreira, J. Timko, M., see Kopéansky, P. Wu, H.-J., see Chen, C.-Y. Timko, M., see Kopéansky, P. Wu, H.-J., see Chen, C.-Y. Timko, M., see Kopéansky, P. Wu, Y., see Shimada, K. Timko, M., see Kopéansky, P. Wu, Z.G., see Nguyen, N.T. Tobiska, L., see Bashtovoi, V. Tobiska, L., see Matthies, G. Xu, H., see Li, D. Tobiska, L., see Polevikov, V. Xu, H., see Li, D. Tohji, K., see Sato, K. Xu, H., see Li, D. TomaSovicova, N., see Kopéansky, P. Toméo, L., see Kopéansky, P. Yamaguchi, H., see Shuchi, S. Tourinho, F.A., see Sousa, E.C. Yamaguchi, H., see Kuwahara, T. Tourinho, F.A., see Campos, A.F.C. Yamane, R., S. Oshiama and M.-K. Park, Magnetically Tourinho, F.A., see Gomes, J.A. suspended virtual divergent channel Tourinho, F.A., see Aquino, R. Yang, H.C., see Hong, C.-Y. Trahms, L., see Eberbeck, D. Yang, S.Y., see Hong, C.-Y. Trahms, L., see Eberbeck, D. Yang, Z., see Liu, T. Trivedi, P., see Mehta, R.V. Yerin, C.V. and V.V. Padalka, Influence of electric field Turek, I., see Kopcansky, P. upon the formation of particles cluster in magnetic fluid Turkov, V.A., see Naletova, V.A. Turkov, V.A., see Naletova, V.A. Zahn, M., see Rosensweig, R.E. 192 Tyatyushkin, A.N., see Naletova, V.A. Zahn, M., see Rinaldi, C. 307 fi *»1n y Author index to volume 289 541 cs i 4] Zahn, M., see Rhodes, S. Zaichenko, A., see Bolshakova, I. 108 Zaichenko, A., I. Bolshakova, N. Mitina, O. Shevchuk, Zeisberger, M., see Miiller, R. 13 A. Bily and V. Lobaz, The synthesis and rheological Zimmermann, G., see Kroell, M. 21 -_ characteristics of colloidal systems containing Znidarsit, A., see Makovec, D. 32 functional magnetic nanoparticles 17 Available online at www.sciencedirect.com FA, \ournal ot science @oinecrs Ma iiateriais ELSEVIER Journal of Magnetism and Magnetic Materials 289 (2005) 542-544 www.elsevier.com/locate/jmmm Subject index to volume 289 Aggregation 9, 234 Colloid 28 Ferrites 184 Aggregation in magnetic fluids 36 Colloidal suspensions 47 Ferrofluid 149, 177, 188, 192, 264, 281, Aggregation processes 105 Colloids 39, 74, 230 289, 307, 328, 331, 346, 356, 473 Anchoring 101 Complex liquids 54 Ferrofluid flows 353 Anisotropy 66 Complex magnetic susceptibility 78, Ferrofluid instabilites 353 Anti-pressure 399 162 Ferrofluid pattern 353 Ants 442 Complex susceptibility 133, 159, 165 Ferrofluid spirals 353 Asymptotic solution 314 Composite material 9 Ferrofluids 13, 47, 54, 58, 84, 115, 152, Autowave 155 Concentration waves 111 181, 199, 268, 295, 303 Contrast media 439 Ferrogels 62 Bacteria 455 Convection 264, 272, 278 Ferrohydrodynamics 360 Bacteria strains 445 Cross-rolls 264 Ferromagnetic particles 392 Binding reaction kinetics 435 Cubic enclosure 272 Ferromagnetic resonance 78, 133, 159 Biocompatibility 466 Ferronematic 101, 152 Biocompatible magnetic fluids 168, 431 Damper 9 Field-induced magnetic birefringence 480 Biodistribution of magnetic particles 428 Damper system 207 Field-induced ordering 58 Biomass 445 Demagnetization 403 Fine magnetic particle 101 Biomaterial 463 Demagnetization factor 192 Fine particle systems 129, 142, 448 Biomedical application 428 Dendrimer 423 Fine-particle system 174 Biomineralization 442 Dendrites 356 Fine-particle systems 74 Birefringence 177, 222 Design optimization 411 Fingering instabilities 339, 364 Blocking phenomena 152 Diamagnetic liquid 389 Finite element method 207 Blood mice 452 Dichroism 177 Finite element solution 346 Boiling heat transfer 257 Dielectric breakdown 415 Finite volume 238 Boundary integral equations 373 Dielectric properties 415 Flow visualization 392 Box-plot distribution 81 Differential pressure 419 Fluorescence 455 Brown relaxation 480 Disjoining pressure 215 FMR 84 Brown rotation 177 Dispersed FePt | FMR line 84 Brownian dynamics 325 Dispersions 325 Forced Rayleigh scattering 39, 97 Brownian motion 392 Double-layer stabilization 50 Fractal aggregate 219 Bubble 382 Drift velocity 318 Fractals 356 Bubbles flows 350 Drop deformation 318 Fraunhoffer diffraction 311 Buckling 335 Droplet 321 Fredericksz transition 101 Droplets flows 350 Free surface 376 Dynamic light scattering 105 Friction factor 314 Capillary rise 376 Carboxymethyldextran 452 Catalase 473 Effective anisotropy constant 162 Glass crystallisation 13 Cation distribution 184 Electric double layered magnetic fluids Growth inhibition 455 Cavitation 260 171 Cell density 445 Electric field 370 Heat pipe 253 Cell proliferation 469 Electrohydrodynamical instability 90 Heat transfer 272, 278 Cellulolytic fungi 473 Energy minimization 192 Heat transport device 257 Chain aggregates 211 ESR 162 Hele-Shaw cell 299 Chitosan 328 Evaporation rate 43 Hele—shaw cell 215, 373 Chlorophyll ratio 459 Hele—Shaw flows 364 Citric ion-stabilized magnetic fluid 253 FePt | High coercivity | Cluster 66 FePt magnetic fluids | High-power FMR 84 Cobalt-ferrite 139 FePt nanoparticles | Homogeneous nucleation 17 Coherent X-rays 47 Ferrite nanoparticles 328 Human IgG 480 doi:10.1016/S0304-8853(05)00234-9 Subject index to volume 289 543 Hyperthermia 476 Magnetic foam 215 Non-linear 165 Hysteresis 442 Magnetic force microscopy 70 Non-linear response 181 Magnetic gels 126 Normal-field instability 346 Impedance spectroscopy 181 Magnetic hyperthermia 13 Nucleic acids biosynthesis 459 Induced birefringence 385 Magnetic liquids 28, 39, 74, 118, 129, 142, Numerical simulation 238, 379 Inductive heating 5 325, 373, 407, 448, 459 Initial susceptibility 211 Magnetic losses 13 Oleic acid 328 Instabilities 350, 379 Magnetic nanoparticles 13, 62, 118, 184, Oleic acid coating 81 Interaction 188 307, 435, 439 Oligoperoxide 17 Interfacial instability 360 Magnetic permeability 219 Ordered structure 93 Interfacial phenomena 192 Magnetic pressure coefficient 111 Orientational ordering 226 Internal flow 260 Magnetic pumping 199 Oxyhemoglobin 452 IR stretching 81 Magnetic recovery 318 Iron 28 Magnetic resonance 129, 136, 142, 146 Pair potential 171 Magnetic stress 192 Particle size distribution 97 Knudsen cell 43 Magnetite 5, 25, 253, 442 Particle tracking velocimetry 392 Magnetization 174, 211 Pastes 325 Labyrinthine patterns 373 Magnetization measurement 21 Peroxidase 473 Laminar flow 314 Magneto-optical effect 115 Phagocytosis 463 Magneto-rheological fluid 321 Laminar pipe-flow 238 Phase transitions 171 Magnetodeformational effect 62 Langevin molecular dynamics simulation Photodynamic therapy 476 234 Magnetodielectric anisotropy 181 Photothermal 295 Langmuir equation 43 Magnetohydrodynamics and electrohy- Plateau rule 215 Levitation 389 drodynamics 325 Polarised neutrons 58, 149 Light scattering 50, 126 Magnetooptical effects 36, 448 Polishing 9 Linear stability 268 Magnetorelaxometry 70, 435 Polyaspartic acid 466 Liquid crystal 101 Magnetorheological suspension 311 Polycaprolactone 5 Liquid crystal thermography 299 Magnetorheology 307 Polydispersed ferrofluids 234 Liquid metal MHD 260 Magnetosomes 70 Polymer gels 126 Lorentz force 370 Magnetotactic bacteria 335 Porous media 275, 278 Lyotropic liquid crystals 115 Magnetoviscosity 307 Power loss 78 Magnetoviscous effect 203, 242, 303 Precipitation 32 Mass transport 331 Macrophages 463 Primary cluster 392 Maxwell equations 379 Maghemite 32, 168 Prisms 28 Meniscus 192 Magneric fluid 403 Prostate specific antigen 480 Micro-channel 396 Magnetic and dielectric fluids 367 Pump 419 Micro-PIV 396 Magnetic and electric forces 367 Microdrop aggregate 90 Magnetic and flow properties 50 Micronucleus test 466 Radiolabeled nanoparticles 431 Magnetic and magneto-optical properties Microsensors 108 Raman spectroscopy 139, 452 431 Microstructure 303 Rayleigh—Marangoni—Benard 268 Minimum energy 188 Reactive particle shell 17 Magnetic birefringence 168, 203 Mirage effect 295 Reciprocating seal 399 Magnetic cluster 9 Miscible magnetic Bond number 364 Reciprocating shaft 407 Magnetic colloids 17, 149, 177 Mitotic index 469 Relaxation 165 Magnetic compound fluid 321 Molecular dynamics 325 Relaxation effects 74 Magnetic compound fluid (MCF) 9 Monte Carlo simulations 230 Relaxation of magnetization 242 Magnetic convection 246 Morphometry 463 Relaxation time 181 Magnetic driving force 257 MR contrast agent 423 Reverse microemulsion 32 Magnetic drug targeting 331 MR imaging 423 Rheological properties 87 Magnetic dynamics 118 MRI contrast agent 328 Rheology 17, 21 Magnetic field 9, 250, 356, 370, 376, 382 Multiphase flow 260 Rietveld refinement 184 Magnetic filaments 335 Multiple scattering 47 Rolls 264 Magnetic fluidized beds 111 Rotating field 335 Magnetic fluids 5, 9, 43, 66, 66, 87, 87, 90, Rotating Hele-Shaw flows 339 93, 97, 105, 108, 136, 136, 146, 155, 162, Nano-technology 9 162, 174, 174, 177, 192, 207, 207, 238, Nanocomposites 139 238, 238, 238, 238, 250, 250, 257, 272, Nanoparticles 25, 32, 246, 275, 452 Scattering patterns 303 278, 278, 292, 299, 311, 321, 321, 321, Nanostructures 58 Seal 43 342, 342, 376, 376, 376, 376, 382, 382, Natural convection 299 Seal gap 407 389, 399, 399, 411, 415, 419, 445, 445, Neel relaxation 13 Seal structure 41] 452, 455, 463, 466, 469, 476 Neel rotation 177 Sealing 419

See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.