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Prof. Nilanjan Chakraborty
Prof. Nilanjan Chakraborty
Professor of Fluid Dynamics, Newcastle University
Verified email at ncl.ac.uk - Homepage
Title
Cited by
Cited by
Year
Laminar natural convection of power-law fluids in a square enclosure with differentially heated side walls subjected to constant temperatures
O Turan, A Sachdeva, N Chakraborty, RJ Poole
Journal of Non-Newtonian Fluid Mechanics 166 (17-18), 1049-1063, 2011
2282011
Unsteady effects of strain rate and curvature on turbulent premixed flames in an inflow–outflow configuration
N Chakraborty, S Cant
Combustion and flame 137 (1-2), 129-147, 2004
2272004
Influence of the Damköhler number on turbulence-scalar interaction in premixed flames. I. Physical insight
N Chakraborty, N Swaminathan
Physics of Fluids 19 (4), 2007
2262007
Laminar natural convection of Bingham fluids in a square enclosure with differentially heated side walls
O Turan, N Chakraborty, RJ Poole
Journal of Non-Newtonian Fluid Mechanics 165 (15-16), 901-913, 2010
2162010
Scalar dissipation rate modeling and its validation
H Kolla, JW Rogerson, N Chakraborty, N Swaminathan
Combustion Science and Technology 181 (3), 518-535, 2009
2152009
Influence of Lewis number on curvature effects in turbulent premixed flame propagation in the thin reaction zones regime
N Chakraborty, RS Cant
Physics of Fluids 17 (10), 2005
1682005
Effects of turbulence on spark ignition in inhomogeneous mixtures: a direct numerical simulation (DNS) study
N CHAKRABORTY*, E Mastorakos, RS Cant
Combustion science and technology 179 (1-2), 293-317, 2007
1362007
Effects of Lewis number on the reactive scalar gradient alignment with local strain rate in turbulent premixed flames
N Chakraborty, M Klein, N Swaminathan
Proceedings of the Combustion Institute 32 (1), 1409-1417, 2009
1312009
Effects of strain rate and curvature on surface density function transport in turbulent premixed flames in the thin reaction zones regime
N Chakraborty, RS Cant
Physics of Fluids 17 (6), 2005
1302005
Effects of Lewis number on flame surface density transport in turbulent premixed combustion
N Chakraborty, RS Cant
Combustion and Flame 158 (9), 1768-1787, 2011
1292011
Scalar dissipation rate modelling for large eddy simulation of turbulent premixed flames
TD Dunstan, Y Minamoto, N Chakraborty, N Swaminathan
Proceedings of the Combustion Institute 34 (1), 1193-1201, 2013
1202013
Laminar Rayleigh-Bénard convection of yield stress fluids in a square enclosure
O Turan, N Chakraborty, RJ Poole
Journal of Non-Newtonian Fluid Mechanics 171, 83-96, 2012
1142012
A priori analysis of the curvature and propagation terms of the flame surface density transport equation for large eddy simulation
N Chakraborty, RS Cant
Physics of Fluids 19 (10), 2007
1142007
A priori direct numerical simulation assessment of algebraic flame surface density models for turbulent premixed flames in the context of large eddy simulation
N Chakraborty, M Klein
Physics of fluids 20 (8), 2008
1122008
The effects of strain rate and curvature on surface density function transport in turbulent premixed methane–air and hydrogen–air flames: A comparative study
N Chakraborty, ER Hawkes, JH Chen, RS Cant
Combustion and Flame 154 (1-2), 259-280, 2008
1062008
Influence of the Damköhler number on turbulence-scalar interaction in premixed flames. II. Model development
N Chakraborty, N Swaminathan
Physics of Fluids 19 (4), 2007
1032007
Curvature and wrinkling of premixed flame kernels—comparisons of OH PLIF and DNS data
S Gashi, J Hult, KW Jenkins, N Chakraborty, S Cant, CF Kaminski
Proceedings of the Combustion Institute 30 (1), 809-817, 2005
1032005
Direct numerical simulation analysis of the flame surface density transport equation in the context of large eddy simulation
N Chakraborty, RS Cant
Proceedings of the Combustion Institute 32 (1), 1445-1453, 2009
1012009
Direct numerical simulations of turbulent flame expansion in fine sprays
AP Wandel, N Chakraborty, E Mastorakos
Proceedings of the Combustion Institute 32 (2), 2283-2290, 2009
992009
The effects of turbulence on molten pool transport during melting and solidification processes in continuous conduction mode laser welding of copper–nickel dissimilar couple
N Chakraborty
Applied Thermal Engineering 29 (17-18), 3618-3631, 2009
982009
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