Energy dissipation in sheared wet granular assemblies
Document Type
Article
Publication Date
9-19-2018
Abstract
Energy dissipation in sheared dry and wet granulates is considered in the presence of an externally applied confining pressure. Discrete element simulations reveal that for sufficiently small confining pressures, the energy dissipation is dominated by the effects related to the presence of cohesive forces between the particles. The residual resistance against shear can be quantitatively explained by a combination of two effects arising in a wet granulate: (i) enhanced friction at particle contacts in the presence of attractive capillary forces and (ii) energy dissipation due to the rupture and reformation of liquid bridges. Coulomb friction at grain contacts gives rise to an energy dissipation which grows linearly with increasing confining pressure for both dry and wet granulates. Because of a lower Coulomb friction coefficient in the case of wet grains, as the confining pressure increases the energy dissipation for dry systems is faster than for wet ones.
Identifier
85053818679 (Scopus)
Publication Title
Physical Review E
External Full Text Location
https://doi.org/10.1103/PhysRevE.98.032905
e-ISSN
24700053
ISSN
24700045
Issue
3
Volume
98
Grant
1521717
Fund Ref
National Science Foundation
Recommended Citation
Kovalcinova, L.; Karmakar, S.; Schaber, M.; Schuhmacher, A. L.; Scheel, M.; Dimichiel, M.; Brinkmann, M.; Seemann, R.; and Kondic, L., "Energy dissipation in sheared wet granular assemblies" (2018). Faculty Publications. 8374.
https://digitalcommons.njit.edu/fac_pubs/8374
