| 2899 - 2899 |
Suspension theology - fundamentals and application to industrial processes
Higashitani K |
| 2901 - 2920 |
Chemical and physical control of the theology of concentrated metal oxide suspensions
Zhou ZW, Scales PJ, Boger DV |
| 2921 - 2926 |
Computer simulation of viscous suspensions
Brady JF |
| 2927 - 2938 |
Simulation of deformation and breakup of large aggregates in flows of viscous fluids
Higashitani K, Iimura K, Sanda H |
| 2939 - 2946 |
Rheology of colloidal suspensions flocculated by reversible bridging
Otsubo Y |
| 2947 - 2955 |
Electroviscous phenomena in colloidal dispersions
van de Ven TGM |
| 2957 - 2966 |
Viscoelastic behavior of ideal bimodal suspensions
Shikata T |
| 2967 - 2977 |
Microstructure evolution and theological responses of hard sphere suspensions
So JH, Yang SM, Hyun JC |
| 2979 - 2989 |
Non-Newtonian viscosity of dense slurries prepared by spherical particles
Usui H, Kishimoto K, Suzuki H |
| 2991 - 2998 |
Particle movement in non-Newtonian slurries: the effect of yield stress on dense medium separation
He YB, Laskowski JS, Klein B |
| 2999 - 3004 |
Images of shear-induced phase separation in a dispersion of hard nanoscale discs
Brown ABD, Rennie AR |
| 3005 - 3010 |
Influence of additive content of anionic polymer dispersant on dense alumina suspension viscosity
Fukuda Y, Togahi T, Suzuki Y, Naito M, Kamiya H |
| 3011 - 3020 |
Shape forming of ceramic powders by manipulating the interparticle pair potential
Lange FF |
| 3021 - 3026 |
The effects of the concentration of a polymer dispersant on apparent viscosity and sedimentation behavior of dense slurries
Tsubaki J, Kato M, Miyazawa M, Kuma T, Mori H |
