Folgen
Shankar Subramaniam
Shankar Subramaniam
Cornell University, Los Alamos National Laboratory, Rutgers University, Iowa State University
Bestätigte E-Mail-Adresse bei iastate.edu
Titel
Zitiert von
Zitiert von
Jahr
A mixing model for turbulent reactive flows based on Euclidean minimum spanning trees
S Subramaniam, SB Pope
Combustion and Flame 115 (4), 487-514, 1998
5771998
Drag law for monodisperse gas–solid systems using particle-resolved direct numerical simulation of flow past fixed assemblies of spheres
S Tenneti, R Garg, S Subramaniam
International journal of multiphase flow 37 (9), 1072-1092, 2011
4822011
Lagrangian–Eulerian methods for multiphase flows
S Subramaniam
Progress in Energy and Combustion Science 39 (2-3), 215-245, 2013
4262013
Particle-resolved direct numerical simulation for gas-solid flow model development
S Tenneti, S Subramaniam
Annual review of fluid mechanics 46, 199-230, 2014
3502014
Modeling average gas–solid heat transfer using particle-resolved direct numerical simulation
B Sun, S Tenneti, S Subramaniam
International Journal of Heat and Mass Transfer 86, 898-913, 2015
1372015
Enskog kinetic theory for monodisperse gas–solid flows
V Garzó, S Tenneti, S Subramaniam, CM Hrenya
Journal of Fluid Mechanics 712, 129-168, 2012
1352012
Accurate numerical estimation of interphase momentum transfer in Lagrangian–Eulerian simulations of dispersed two-phase flows
R Garg, C Narayanan, D Lakehal, S Subramaniam
International Journal of Multiphase Flow 33 (12), 1337-1364, 2007
1192007
Pseudo-turbulent gas-phase velocity fluctuations in homogeneous gas–solid flow: fixed particle assemblies and freely evolving suspensions
M Mehrabadi, S Tenneti, R Garg, S Subramaniam
Journal of Fluid Mechanics 770, 210-246, 2015
1162015
A test method for determining adhesion forces and Hamaker constants of cementitious materials using atomic force microscopy
G Lomboy, S Sundararajan, K Wang, S Subramaniam
Cement and concrete research 41 (11), 1157-1166, 2011
1122011
Role of fluid heating in dense gas–solid flow as revealed by particle-resolved direct numerical simulation
S Tenneti, B Sun, R Garg, S Subramaniam
International Journal of Heat and Mass Transfer 58 (1-2), 471-479, 2013
1062013
Direct numerical simulation of gas–solid suspensions at moderate Reynolds number: quantifying the coupling between hydrodynamic forces and particle velocity fluctuations
S Tenneti, R Garg, CM Hrenya, RO Fox, S Subramaniam
Powder Technology 203 (1), 57-69, 2010
1032010
A fully coupled quadrature-based moment method for dilute to moderately dilute fluid–particle flows
A Passalacqua, RO Fox, R Garg, S Subramaniam
Chemical Engineering Science 65 (7), 2267-2283, 2010
1022010
A probability density function method for turbulent mixing and combustion on three-dimensional unstructured deforming meshes
S Subramaniam, DC Haworth
International Journal of Engine Research 1 (2), 171-190, 2000
1002000
Statistical modeling of sprays using the droplet distribution function
S Subramaniam
Physics of Fluids 13 (3), 624-642, 2001
962001
Statistical modeling of sprays using the droplet distribution function
S Subramaniam
Physics of Fluids 13 (3), 624-642, 2001
962001
Statistical modeling of sprays using the droplet distribution function
S Subramaniam
Physics of Fluids 13 (3), 624-642, 2001
962001
Comparison of mixing model performance for nonpremixed turbulent reactive flow
S Subramaniam, SB Pope
Combustion and Flame 117 (4), 732-754, 1999
941999
Statistical representation of a spray as a point process
S Subramaniam
Physics of Fluids 12 (10), 2413-2431, 2000
872000
A numerically convergent Lagrangian–Eulerian simulation method for dispersed two-phase flows
R Garg, C Narayanan, S Subramaniam
International Journal of Multiphase Flow 35 (4), 376-388, 2009
862009
A review of granular flow in screw feeders and conveyors
D Minglani, A Sharma, H Pandey, R Dayal, JB Joshi, S Subramaniam
Powder Technology 366, 369-381, 2020
832020
Das System kann den Vorgang jetzt nicht ausführen. Versuchen Sie es später erneut.
Artikel 1–20