| 1 |
Controlled-crystallinity of SiO2/TiO2 hollow nanoparticles and their electroresponsive behaviors
Kim BM, Park SH, Lee SA
Journal of Industrial and Engineering Chemistry, 104, 203, 2021 |
| 2 |
Onsager 이론으로 확장한 Maxwell-Wagner 분극 모델에 의한 전기유변 현상 모사
김영대
Korean Chemical Engineering Research, 58(3), 480, 2020 |
| 3 |
High electrorheological effect in Bi1.8Fe1.2SbO7 suspensions
Egorysheva AV, Kraev AS, Gajtko OM, Kusova TV, Baranchikov AE, Agafonov AV, Ivriov VK
Powder Technology, 360, 96, 2020 |
| 4 |
Highly uniform silica nanoparticles with finely controlled sizes for enhancement of electro-responsive smart fluids
Lee SG
Journal of Industrial and Engineering Chemistry, 77, 426, 2019 |
| 5 |
전기유변현상 해석을 위하여 Onsager 이론으로 확장한 Maxwell-Wagner 분극 모델
김영대
Korean Chemical Engineering Research, 56(5), 767, 2018 |
| 6 |
Taylor-Couette flow of electrorheological fluids under electrical double layer phenomenon
Dhar J, Bandopadhyay A, Chakraborty S
Journal of Non-Newtonian Fluid Mechanics, 223, 165, 2015 |
| 7 |
The Effects of Particle Conductivity on the Electrorheological Properties of Functionalized MCNT-Coated Doublet-Shaped Anisotropic Microspheres
Hwang JK, Shin K, Lim HS, Cho JC, Kim JW, Suh KD
Macromolecular Research, 20(4), 391, 2012 |
| 8 |
Analysis of the flow behavior of electrorheological fluids with the aligned structure reformation
Seo YP, Choi HJ, Seo Y
Polymer, 52(25), 5695, 2011 |
| 9 |
The electrorheological response of elongated particles
Kor YK, See H
Rheologica Acta, 49(7), 741, 2010 |
| 10 |
Synthesis and electrorheological properties of polar molecule-dominated TiO (2) particles with high yield stress
Liu XH, Guo JJ, Cheng YC, Xu GJ, Li Y, Cui P
Rheologica Acta, 49(8), 837, 2010 |
