粒子径分布を考慮したキューブ状ヘマタイト粒子分散系を対象とした擬2次元モンテカルロ・シミュレーション(外部磁場が作用しない場合)

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Published in	日本機械学会論文集 Vol. 89; no. 924; p. 23-00111
Main Author	岡田, 和也
Format	Journal Article
Language	Japanese
Published	一般社団法人日本機械学会 2023
Subjects	Aggregation phenomena Cubic hematite particle Monte Carlo simulation Particle size distribution Regime change
Online Access	Get full text
ISSN	2187-9761
DOI	10.1299/transjsme.23-00111

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Author	岡田, 和也
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References	Okada, K. and Satoh, A., Quasi-two-dimensional Brownian dynamics simulations of the regime change in the aggregate structures of cubic haematite particles in a rotating magnetic field, Molecular Physics, Vol. 120 (2022b), p.e2038297. Satoh, A., Introduction to Practice of Molecular Simulation: Molecular Dynamics, Monte Carlo, Brownian Dynamics, Lattice Boltzmann and Dissipative Particle Dynamics (2010), Elsevier Insights. Theis-Bröhl, K., Gutfreund, P., Vorobiev, A., Wolff, M., Toperverg, B. P., Dura, J. A. and Borchers, J. A., Self assembly of magnetic nanoparticles at silicon surfaces, Soft Matter, Vol.11 (2015), pp.4695–4704. Aoshima, M. and Satoh, A., Two-dimensional Monte Carlo simulations of a colloidal dispersion composed of polydisperse ferromagnetic particles in an applied magnetic field, Journal of colloid and interface science, Vol.288 (2005), pp.475–488. Duncan, P. D. and Camp, P. J., Structure and dynamics in a monolayer of dipolar spheres, The Journal of chemical physics, Vol.121 (2004), pp.11322–11331. Linse, P., Quasi-2d fluids of dipolar superballs in an external field, Soft Matter, Vol.11 (2015), pp.3900–3912. Okada, K. and Satoh, A., Brownian dynamics simulations of a cubic haematite particle suspension with a more effective treatment of steric layer interactions, Molecular Physics, Vol. 118 (2020), p. e1740806. Aoshima, M. and Satoh, A., Two-dimensional Monte Carlo simulations of a polydisperse colloidal dispersion composed of ferromagnetic particles for the case of no external magnetic field, Journal of colloid and interface science, Vol.280 (2004), pp.83–90. Dempster, J. M., Zhang, R. and De La Cruz, M. O., Self-replication with magnetic dipolar colloids, Physical Review E, Vol.92 (2015), p.042305. Castillo, S. I., Pompe, C. E., Van Mourik, J., Verbart, D. M., Thies-Weesie, D. M., De Jongh, P. E. and Philipse, A. P., Colloidal cubes for the enhanced degradation of organic dyes, Journal of Materials Chemistry A, Vol.2 (2014), pp.10193–10201. Satoh, A., Introduction to Molecular-Microsimulation of Colloidal Dispersions (2003), Elsevier. Aoshima, M., Ozaki, M. and Satoh, A., Structural analysis of self-assembled lattice structures composed of cubic hematite particles, Journal of Physical Chemistry, Vol.116 (2012), pp.17862–17871. Okada, K. and Satoh, A., Dependence of the regime change in particle aggregates on the composition ratio of magnetic cubic particles with different magnetic moment directions, Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 557 (2018), pp.146–154. Schmidt, A. M., Thermoresponsive magnetic colloids, Colloid and Polymer Science, Vol.285 (2007), pp.953–966. Tavares, J. M., Weis, J. J. and da Gama, M. T., Quasi-two-dimensional dipolar fluid at low densities: Monte Carlo simulations and theory, Physical Review E, Vol.65 (2002), p.061201. Donaldson, J. G., Linse, P. and Kantorovich, S. S., How cube-like must magnetic nanoparticles be to modify their self-assembly?, Nanoscale, Vol.9 (2017), pp.6448–6462. Domingos, J. L., Peeters, F. M. and Ferreira, W. P., Self-assembly of rigid magnetic rods consisting of single dipolar beads in two dimensions, Physical Review E, Vol.96 (2017), p.012603. Sugimoto, T., Itoh, H. and Mochida, T., Shape control of monodisperse hematite particles by organic additives in the gel–sol system, Journal of Colloid and Interface Science, Vol.205 (1998), pp.42–52. Wereley, N. M. (Ed.), Magnetorheology: Advances and Applications (2013), Royal Society of Chemistry. Okada, K. and Satoh, A., Quasi-2D Monte Carlo simulations of the regime change in the aggregates of magnetic cubic particles on a material surface, Molecular Physics, Vol.115 (2017), pp.683–701. Okada, K. and Satoh, A., Aggregation phenssomena and regime change in a magnetic cubic particle suspension in an alternating magnetic field via quasi-two-dimensional Brownian dynamics, Molecular Physics, Vol. 120 (2022a), p.e2096511. Bullough, W. A. (Ed.), Electro-Rheological Fluids, Magneto-Rheological Suspensions and Associated Technology (1996), World Scientific. de Folter, J. W., Hutter, E. M., Castillo, S. I., Klop, K. E., Philipse, A. P. and Kegel, W. K., Particle shape anisotropy in Pickering emulsions: cubes and peanuts, Langmuir, Vol.30 (2014), pp.955–964. Lee, S. H., Park, S. Y., Lee, Y. J., Yi, G. R., Sacanna, S. and Kim, D. H., Diffusivity control of magnetic cube-particle chain by external magnetic field, Applied Physics Letters, Vol.111 (2017), p.132401. Rossi, L., Sacanna, S., Irvine, W. T., Chaikin, P. M., Pine, D. J. and Philipse, A. P., Cubic crystals from cubic colloids, Soft Matter, Vol.7 (2011), pp.4139–4142. Golovin, Y. I., Gribanovsky, S. L., Golovin, D. Y., Klyachko, N. L., Majouga, A. G., Master, A. M., Marina, S. and Kabanov, A. V., Towards nanomedicines of the future: Remote magneto-mechanical actuation of nanomedicines by alternating magnetic fields, Journal of Controlled Release, Vol.219 (2015), pp.43–60. Meijer, J. M., Hagemans, F., Rossi, L., Byelov, D. V., Castillo, S. I., Snigirev, A., Snigireva, I., Philipse, A. P. and Petukhov, A. V., Self-assembly of colloidal cubes via vertical deposition, Langmuir, Vol.28 (2012), pp.7631–7638. Pham, A. T., Zhuang, Y., Detwiler, P., Socolar, J. E., Charbonneau, P. and Yellen, B. B., Phase diagram and aggregation dynamics of a monolayer of paramagnetic colloids, Physical Review E, Vol.95 (2017), p.052607. Ozaki, M., Egami, T., Sugiyama, N. and Matijević, E., Agglomeration in colloidal hematite dispersions due to weak magnetic interactions: II. The effects of particle size and shape, Journal of colloid and interface science, Vol.126 (1988), pp.212–219. Rossi, L., Donaldson, J. G., Meijer, J. M., Petukhov, A. V., Kleckner, D., Kantorovich, S. S., Lrvine, M. T., Philipse, A. P. and Sacanna, S., Self-organization in dipolar cube fluids constrained by competing anisotropies, Soft Matter, Vol.14 (2018), pp.1080–1087.
References_xml	– reference: Dempster, J. M., Zhang, R. and De La Cruz, M. O., Self-replication with magnetic dipolar colloids, Physical Review E, Vol.92 (2015), p.042305. – reference: de Folter, J. W., Hutter, E. M., Castillo, S. I., Klop, K. E., Philipse, A. P. and Kegel, W. K., Particle shape anisotropy in Pickering emulsions: cubes and peanuts, Langmuir, Vol.30 (2014), pp.955–964. – reference: Rossi, L., Sacanna, S., Irvine, W. T., Chaikin, P. M., Pine, D. J. and Philipse, A. P., Cubic crystals from cubic colloids, Soft Matter, Vol.7 (2011), pp.4139–4142. – reference: Donaldson, J. G., Linse, P. and Kantorovich, S. S., How cube-like must magnetic nanoparticles be to modify their self-assembly?, Nanoscale, Vol.9 (2017), pp.6448–6462. – reference: Golovin, Y. I., Gribanovsky, S. L., Golovin, D. Y., Klyachko, N. L., Majouga, A. G., Master, A. M., Marina, S. and Kabanov, A. V., Towards nanomedicines of the future: Remote magneto-mechanical actuation of nanomedicines by alternating magnetic fields, Journal of Controlled Release, Vol.219 (2015), pp.43–60. – reference: Pham, A. T., Zhuang, Y., Detwiler, P., Socolar, J. E., Charbonneau, P. and Yellen, B. B., Phase diagram and aggregation dynamics of a monolayer of paramagnetic colloids, Physical Review E, Vol.95 (2017), p.052607. – reference: Domingos, J. L., Peeters, F. M. and Ferreira, W. P., Self-assembly of rigid magnetic rods consisting of single dipolar beads in two dimensions, Physical Review E, Vol.96 (2017), p.012603. – reference: Okada, K. and Satoh, A., Quasi-two-dimensional Brownian dynamics simulations of the regime change in the aggregate structures of cubic haematite particles in a rotating magnetic field, Molecular Physics, Vol. 120 (2022b), p.e2038297. – reference: Castillo, S. I., Pompe, C. E., Van Mourik, J., Verbart, D. M., Thies-Weesie, D. M., De Jongh, P. E. and Philipse, A. P., Colloidal cubes for the enhanced degradation of organic dyes, Journal of Materials Chemistry A, Vol.2 (2014), pp.10193–10201. – reference: Theis-Bröhl, K., Gutfreund, P., Vorobiev, A., Wolff, M., Toperverg, B. P., Dura, J. A. and Borchers, J. A., Self assembly of magnetic nanoparticles at silicon surfaces, Soft Matter, Vol.11 (2015), pp.4695–4704. – reference: Okada, K. and Satoh, A., Quasi-2D Monte Carlo simulations of the regime change in the aggregates of magnetic cubic particles on a material surface, Molecular Physics, Vol.115 (2017), pp.683–701. – reference: Satoh, A., Introduction to Molecular-Microsimulation of Colloidal Dispersions (2003), Elsevier. – reference: Sugimoto, T., Itoh, H. and Mochida, T., Shape control of monodisperse hematite particles by organic additives in the gel–sol system, Journal of Colloid and Interface Science, Vol.205 (1998), pp.42–52. – reference: Okada, K. and Satoh, A., Dependence of the regime change in particle aggregates on the composition ratio of magnetic cubic particles with different magnetic moment directions, Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 557 (2018), pp.146–154. – reference: Aoshima, M. and Satoh, A., Two-dimensional Monte Carlo simulations of a polydisperse colloidal dispersion composed of ferromagnetic particles for the case of no external magnetic field, Journal of colloid and interface science, Vol.280 (2004), pp.83–90. – reference: Okada, K. and Satoh, A., Brownian dynamics simulations of a cubic haematite particle suspension with a more effective treatment of steric layer interactions, Molecular Physics, Vol. 118 (2020), p. e1740806. – reference: Aoshima, M. and Satoh, A., Two-dimensional Monte Carlo simulations of a colloidal dispersion composed of polydisperse ferromagnetic particles in an applied magnetic field, Journal of colloid and interface science, Vol.288 (2005), pp.475–488. – reference: Okada, K. and Satoh, A., Aggregation phenssomena and regime change in a magnetic cubic particle suspension in an alternating magnetic field via quasi-two-dimensional Brownian dynamics, Molecular Physics, Vol. 120 (2022a), p.e2096511. – reference: Duncan, P. D. and Camp, P. J., Structure and dynamics in a monolayer of dipolar spheres, The Journal of chemical physics, Vol.121 (2004), pp.11322–11331. – reference: Schmidt, A. M., Thermoresponsive magnetic colloids, Colloid and Polymer Science, Vol.285 (2007), pp.953–966. – reference: Tavares, J. M., Weis, J. J. and da Gama, M. T., Quasi-two-dimensional dipolar fluid at low densities: Monte Carlo simulations and theory, Physical Review E, Vol.65 (2002), p.061201. – reference: Meijer, J. M., Hagemans, F., Rossi, L., Byelov, D. V., Castillo, S. I., Snigirev, A., Snigireva, I., Philipse, A. P. and Petukhov, A. V., Self-assembly of colloidal cubes via vertical deposition, Langmuir, Vol.28 (2012), pp.7631–7638. – reference: Rossi, L., Donaldson, J. G., Meijer, J. M., Petukhov, A. V., Kleckner, D., Kantorovich, S. S., Lrvine, M. T., Philipse, A. P. and Sacanna, S., Self-organization in dipolar cube fluids constrained by competing anisotropies, Soft Matter, Vol.14 (2018), pp.1080–1087. – reference: Linse, P., Quasi-2d fluids of dipolar superballs in an external field, Soft Matter, Vol.11 (2015), pp.3900–3912. – reference: Ozaki, M., Egami, T., Sugiyama, N. and Matijević, E., Agglomeration in colloidal hematite dispersions due to weak magnetic interactions: II. The effects of particle size and shape, Journal of colloid and interface science, Vol.126 (1988), pp.212–219. – reference: Wereley, N. M. (Ed.), Magnetorheology: Advances and Applications (2013), Royal Society of Chemistry. – reference: Aoshima, M., Ozaki, M. and Satoh, A., Structural analysis of self-assembled lattice structures composed of cubic hematite particles, Journal of Physical Chemistry, Vol.116 (2012), pp.17862–17871. – reference: Lee, S. H., Park, S. Y., Lee, Y. J., Yi, G. R., Sacanna, S. and Kim, D. H., Diffusivity control of magnetic cube-particle chain by external magnetic field, Applied Physics Letters, Vol.111 (2017), p.132401. – reference: Satoh, A., Introduction to Practice of Molecular Simulation: Molecular Dynamics, Monte Carlo, Brownian Dynamics, Lattice Boltzmann and Dissipative Particle Dynamics (2010), Elsevier Insights. – reference: Bullough, W. A. (Ed.), Electro-Rheological Fluids, Magneto-Rheological Suspensions and Associated Technology (1996), World Scientific.
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SubjectTerms	Aggregation phenomena Cubic hematite particle Monte Carlo simulation Particle size distribution Regime change
Title	粒子径分布を考慮したキューブ状ヘマタイト粒子分散系を対象とした擬2次元モンテカルロ・シミュレーション(外部磁場が作用しない場合)
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