| Alignment of vorticity and scalar gradient with strain rate in simulated Navier–Stokes turbulence WT Ashurst, AR Kerstein, RM Kerr, CH Gibson The Physics of fluids 30 (8), 2343-2353, 1987 | 975 | 1987 |
| Chemical model of coal devolatilization using percolation lattice statistics DM Grant, RJ Pugmire, TH Fletcher, AR Kerstein Energy & Fuels 3 (2), 175-186, 1989 | 620 | 1989 |
| Field equation for interface propagation in an unsteady homogeneous flow field AR Kerstein, WT Ashurst, FA Williams Physical Review A 37 (7), 2728, 1988 | 559 | 1988 |
| Chemical percolation model for devolatilization. 3. Direct use of carbon-13 NMR data to predict effects of coal type TH Fletcher, AR Kerstein, RJ Pugmire, MS Solum, DM Grant Energy & Fuels 6 (4), 414-431, 1992 | 531 | 1992 |
| Single-column model intercomparison for a stably stratified atmospheric boundary layer J Cuxart, AAM Holtslag, RJ Beare, E Bazile, A Beljaars, A Cheng, ... Boundary-Layer Meteorology 118, 273-303, 2006 | 422 | 2006 |
| A linear-eddy model of turbulent scalar transport and mixing AR Kerstein Combustion Science and Technology 60 (4-6), 391-421, 1988 | 417 | 1988 |
| FLASHCHAIN theory for rapid coal devolatilization kinetics. 1. Formulation S Niksa, AR Kerstein Energy & fuels 5 (5), 647-665, 1991 | 415 | 1991 |
| One-dimensional turbulence: model formulation and application to homogeneous turbulence, shear flows, and buoyant stratified flows AR Kerstein Journal of Fluid Mechanics 392, 277-334, 1999 | 410 | 1999 |
| Chemical percolation model for devolatilization. 2. Temperature and heating rate effects on product yields TH Fletcher, AR Kerstein, RJ Pugmire, DM Grant Energy & Fuels 4 (1), 54-60, 1990 | 373 | 1990 |
| Linear-eddy modelling of turbulent transport. Part 6. Microstructure of diffusive scalar mixing fields AR Kerstein Journal of Fluid Mechanics 231, 361-394, 1991 | 356 | 1991 |
| Linear-eddy modeling of turbulent transport. II: Application to shear layer mixing AR Kerstein Combustion and Flame 75 (3-4), 397-413, 1989 | 247 | 1989 |
| Critical properties of the void percolation problem for spheres WT Elam, AR Kerstein, JJ Rehr Physical review letters 52 (17), 1516, 1984 | 216 | 1984 |
| A petascale direct numerical simulation study of the modelling of flame wrinkling for large-eddy simulations in intense turbulence ER Hawkes, O Chatakonda, H Kolla, AR Kerstein, JH Chen Combustion and flame 159 (8), 2690-2703, 2012 | 209 | 2012 |
| One-dimensional turbulence: vector formulation and application to free shear flows AR Kerstein, WT Ashurst, S Wunsch, V Nilsen Journal of Fluid Mechanics 447, 85-109, 2001 | 202 | 2001 |
| Linear-eddy modelling of turbulent transport. Part 7. Finite-rate chemistry and multi-stream mixing AR Kerstein Journal of Fluid Mechanics 240, 289-313, 1992 | 190 | 1992 |
| Linear-eddy modelling of turbulent transport. Part 3. Mixing and differential molecular diffusion in round jets AR Kerstein Journal of Fluid Mechanics 216, 411-435, 1990 | 174 | 1990 |
| ‘One-dimensional turbulence’simulation of turbulent jet diffusion flames: model formulation and illustrative applications T Echekki, AR Kerstein, TD Dreeben, JY Chen Combustion and Flame 125 (3), 1083-1105, 2001 | 173 | 2001 |
| Linear-eddy modeling of turbulent transport. Part 4. Structure of diffusion flames AR Kerstein Combustion Science and Technology 81 (1-3), 75-96, 1992 | 152 | 1992 |
| Near-wall LES closure based on one-dimensional turbulence modeling RC Schmidt, AR Kerstein, S Wunsch, V Nilsen Journal of Computational Physics 186 (1), 317-355, 2003 | 129 | 2003 |
| One-dimensional turbulence: Variable-density formulation and application to mixing layers WT Ashurst, AR Kerstein Physics of Fluids 17 (2), 2005 | 128 | 2005 |
