Monte Carlo methods in statistical physics MEJ Newman, GT Barkema Clarendon Press, 1999 | 3730 | 1999 |
Event-based relaxation of continuous disordered systems GT Barkema, N Mousseau Physical review letters 77 (21), 4358, 1996 | 589 | 1996 |
Traveling through potential energy landscapes of disordered materials: The activation-relaxation technique N Mousseau, GT Barkema Physical Review E 57 (2), 2419, 1998 | 308 | 1998 |
High-quality continuous random networks GT Barkema, N Mousseau Physical Review B 62 (8), 4985, 2000 | 307 | 2000 |
Fitting the Stillinger–Weber potential to amorphous silicon RLC Vink, GT Barkema, WF Van der Weg, N Mousseau Journal of non-crystalline solids 282 (2-3), 248-255, 2001 | 215 | 2001 |
An introduction to Monte Carlo methods JC Walter, GT Barkema Physica A: Statistical Mechanics and its Applications 418, 78-87, 2015 | 214 | 2015 |
Monte Carlo simulation of ice models GT Barkema, MEJ Newman Physical Review E 57 (1), 1155, 1998 | 156 | 1998 |
Raman spectra and structure of amorphous Si RLC Vink, GT Barkema, WF Van Der Weg Physical Review B 63 (11), 115210, 2001 | 142 | 2001 |
Anomalous dynamics of unbiased polymer translocation through a narrow pore D Panja, GT Barkema, RC Ball Journal of Physics: Condensed Matter 19 (43), 432202, 2007 | 134 | 2007 |
Pore-blockade times for field-driven polymer translocation H Vocks, D Panja, GT Barkema, RC Ball Journal of Physics: Condensed Matter 20 (9), 095224, 2008 | 121 | 2008 |
Structure of twisted and buckled bilayer graphene SK Jain, V Juričić, GT Barkema 2D Materials 4 (1), 015018, 2016 | 111 | 2016 |
Passage times for unbiased polymer translocation through a narrow pore JK Wolterink, GT Barkema, D Panja Physical review letters 96 (20), 208301, 2006 | 111 | 2006 |
Monte Carlo study of the random-field Ising model MEJ Newman, GT Barkema Physical Review E 53 (1), 393, 1996 | 108 | 1996 |
Activated mechanisms in amorphous silicon: An activation-relaxation-technique study N Mousseau, GT Barkema Physical Review B 61 (3), 1898, 2000 | 97 | 2000 |
Electrophoresis of charged polymers: simulation and scaling in a lattice model of reptation GT Barkema, JF Marko, B Widom Physical Review E 49 (6), 5303, 1994 | 97 | 1994 |
Reaction-diffusion front for in one dimension GT Barkema, MJ Howard, JL Cardy Physical Review E 53 (3), R2017, 1996 | 90 | 1996 |
Identification of relaxation and diffusion mechanisms in amorphous silicon GT Barkema, N Mousseau Physical review letters 81 (9), 1865, 1998 | 84 | 1998 |
Monte Carlo study of multiply crosslinked semiflexible polymer networks EM Huisman, C Storm, GT Barkema Physical Review E—Statistical, Nonlinear, and Soft Matter Physics 78 (5 …, 2008 | 78 | 2008 |
Through the eye of the needle: recent advances in understanding biopolymer translocation D Panja, GT Barkema, AB Kolomeisky Journal of Physics: Condensed Matter 25 (41), 413101, 2013 | 74 | 2013 |
Diffusion mechanism of Cu adatoms on a Cu (001) surface C Lee, GT Barkema, M Breeman, A Pasquarello, R Car Surface science 306 (3), L575-L578, 1994 | 74 | 1994 |