(73) Satoh, A.
Monte
Carlo simulations on phase change in aggregate structures of
ferromagnetic spherocylinder particles,
Colloid and Surfaces A, Vol. 504, pp.
393–399 , 2016,
9.
(74) Satoh, A.
Control of the
orientational characteristics of disk-like hematite particles by a simple shear
flow,
Mechanical Engineering Letters, Vo.2,
16-00314, 2016.
(75)
Satoh, A. and Okada, K..
Quasi-2D Monte Carlo
simulations of the regime change in the aggregates of magnetic cubic particles
on a material surface,
Molecular
Physics, Vol.115, No. 6, pp. 683-701, 2017,
2.
(76) Okada, K.
and Satoh, A.
Regime of aggregate structures
and magneto-rheological characteristics of a magnetic rod-like particle
suspension:
Monte Carlo and Brownian dynamics
simulations,
Journal of Magnetism and
Magnetic Materials, Vol. 437, PP. 29-41, 2017, 9.
(77)
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,
Colloid and Surfaces
A, Vol. 557, pp. 146-154 , 2018.
(78) Okada, K.
and Satoh, A.
3D Monte Carlo simulations on
the aggregate structures of a suspension composed of cubic hematite
particles,
Molecular Physics, Vol. 116,
pp. 2300-2309, 2018.
(79) Satoh,
A. and Cuadra, C.
Experimental verification of
negative magnetorheological characteristics in spindle-like hematite
particle suspensions,
Journal of
Magnetism and Magnetic Materials, Vol. 469, pp. 606-612, 2018, 9.
(80)
Serantes, D., Chantrell, R. W., Gavilan, H., Morales, M. del P.,
Chubykalo-Fesenko, O., Baldomir, D. and Satoh, A.
Anisotropic magnetic nanoparticles for
biomedicine: bridging frequency separated AC-field controlled domains
of actuation,
Physical
Chemistry Chemical Physics, Vol. 20, pp. 30445-30454 2018, 12.
(81) Satoh,
A.
Flow characteristics of a microjet arising
in an electro-conjugate fluid under a high electric field,
Molecular Physics, Vol. 117, pp. 1813-1824,
2019.
(82) Suzuki, S., Satoh, A., and Wada,
S.
Monte Carlo simulations of magnetic
particle suspensions with a simple assessment method for the particle
overlap
between magnetic
spheroids,
Molecular Physics,Vol. 118, 3, pp.
e1607915 (18 pages), 2020.
(83) Okada, K. and Satoh, A.
Evaluation of the translational and
rotational diffusion coefficients of a cubic
particle (For the application to
Brownian dynamics simulations),
Molecular Physics, Vol. 118, 5, e1631498 (13 pages), 2020.
(84) Suzuki, S.
and Satoh, A.
Influence of the cluster
formation in a magnetic particle suspention on heat production effect in an
alternating
magnetic
field,
Colloid and Polymer Science, Vol. 297, pp.
1265-1273, 2019.
(85) Satoh, A.
Feasibility of the multi-particle collision
dynamics method as a simulation technique
for a magnetic particle suspension,
Molecular Simulation, Vol. 46, 3, pp. 213-223, 2020.
(86) Okada, K. and
Satoh, A.
Sedimentation characteristics of
spherical and rod-like particles
in the
gravitational field by Brownian dynamics
simulations
(For the improvement of the
visibility of small lakes and ponds),
Environmental Fluid Mechanics, Vol. 20, pp. 765-790, 2020.
(87) Satoh, A. ,
Okada, K. and Futamura, M.
Attachment
characteristics of charged magnetic cubic particles to two parallel electrodes
(3D Monte Carlo simulations) ,
Molecular
Simulation, Vol. 46, 11, pp. 837-852, 2020.
(88) Okada, K. and Satoh, A.
Brownian dynamics simulations of a cubic
hematite particle suspension
with a more
effective treatment of steric layer interactions
Molecular Physics, Molecular Physics, Volume
118, 17, e1740806, 2020.
(89) Yamanouchi, T. and Satoh, A.
Trapping characteristics of magnetic rod-like
particles flowing in a cylindrical pipe by means
of
a
non-uniform
Molecular Physics, Vol. 118, 23,
e1778201, 2020.
(90)Arciniegas, M. P., Castelli, A., Brescia,
R., Serantes, D., Ruta, S., Hovorka, O., Satoh, A., Chantrell, R., and
Pellegrino, T.
Unveiling the dynamical assembly of
magnetic nanocrystal zig‐zag chains via in situ TEM Imaging in
Liquid
Small, Vol. 16, 25, 1907419,
2020.