| Review of the national ignition campaign 2009-2012 J Lindl, O Landen, J Edwards, E Moses, NIC team Physics of Plasmas 21 (2), 2014 | 726 | 2014 |
| Burning plasma achieved in inertial fusion AB Zylstra, OA Hurricane, DA Callahan, AL Kritcher, JE Ralph, HF Robey, ... Nature 601 (7894), 542-548, 2022 | 348 | 2022 |
| Lawson criterion for ignition exceeded in an inertial fusion experiment H Abu-Shawareb, R Acree, P Adams, J Adams, B Addis, R Aden, P Adrian, ... Physical review letters 129 (7), 075001, 2022 | 241 | 2022 |
| Design of magnetized liner inertial fusion experiments using the Z facility AB Sefkow, SA Slutz, JM Koning, MM Marinak, KJ Peterson, DB Sinars, ... Physics of Plasmas 21 (7), 2014 | 180 | 2014 |
| Design of inertial fusion implosions reaching the burning plasma regime AL Kritcher, CV Young, HF Robey, CR Weber, AB Zylstra, OA Hurricane, ... Nature Physics 18 (3), 251-258, 2022 | 122 | 2022 |
| Short-wavelength and three-dimensional instability evolution in National Ignition Facility ignition capsule designs DS Clark, SW Haan, AW Cook, MJ Edwards, BA Hammel, JM Koning, ... Physics of Plasmas 18 (8), 2011 | 103 | 2011 |
| Three-dimensional modeling and hydrodynamic scaling of National Ignition Facility implosions DS Clark, CR Weber, JL Milovich, AE Pak, DT Casey, BA Hammel, DD Ho, ... Physics of Plasmas 26 (5), 2019 | 92 | 2019 |
| Simulations of electrothermal instability growth in solid aluminum rods KJ Peterson, EP Yu, DB Sinars, ME Cuneo, SA Slutz, JM Koning, ... Physics of Plasmas 20 (5), 2013 | 83 | 2013 |
| Flux: Overcoming scheduling challenges for exascale workflows DH Ahn, N Bass, A Chu, J Garlick, M Grondona, S Herbein, HI Ingólfsson, ... Future Generation Computer Systems 110, 202-213, 2020 | 68 | 2020 |
| Simulation of self-generated magnetic fields in an inertial fusion hohlraum environment WA Farmer, JM Koning, DJ Strozzi, DE Hinkel, LF Berzak Hopkins, ... Physics of Plasmas 24 (5), 2017 | 60 | 2017 |
| A discrete differential forms framework for computational electromagnetism P Castillo, J Koning, R Rieben, D White Computer Modeling in Engineering and Sciences 5 (4), 331-345, 2004 | 42 | 2004 |
| Deep learning for NLTE spectral opacities G Kluth, KD Humbird, BK Spears, JL Peterson, HA Scott, MV Patel, ... Physics of Plasmas 27 (5), 2020 | 35 | 2020 |
| Imposed magnetic field and hot electron propagation in inertial fusion hohlraums DJ Strozzi, LJ Perkins, MM Marinak, DJ Larson, JM Koning, BG Logan Journal of Plasma Physics 81 (6), 475810603, 2015 | 32 | 2015 |
| Computing solenoidal eigenmodes of the vector Helmholtz equation: A novel approach DA White, JM Koning IEEE transactions on magnetics 38 (5), 3420-3425, 2002 | 32 | 2002 |
| Modeling and projecting implosion performance for the National Ignition Facility DS Clark, CR Weber, AL Kritcher, JL Milovich, PK Patel, SW Haan, ... Nuclear Fusion 59 (3), 032008, 2018 | 31 | 2018 |
| Heat transport modeling of the dot spectroscopy platform on NIF WA Farmer, OS Jones, MA Barrios, DJ Strozzi, JM Koning, GD Kerbel, ... Plasma Physics and Controlled Fusion 60 (4), 044009, 2018 | 26 | 2018 |
| Enabling machine learning-ready HPC ensembles with Merlin JL Peterson, B Bay, J Koning, P Robinson, J Semler, J White, R Anirudh, ... Future Generation Computer Systems 131, 255-268, 2022 | 22 | 2022 |
| Merlin: enabling machine learning-ready HPC ensembles JL Peterson, K Athey, PT Bremer, V Castillo, F Di Natale, JE Field, D Fox, ... Lawrence Livermore National Lab.(LLNL), Livermore, CA (United States), 2019 | 22 | 2019 |
| Development and application of compatible discretizations of Maxwell˘s equations DA White, JM Koning, RN Rieben Compatible spatial discretizations, 209-234, 2006 | 21 | 2006 |
| Vector finite-element modeling of the full-wave Maxwell equations to evaluate power loss in bent optical fibers J Koning, RN Rieben, GH Rodrigue Journal of lightwave technology 23 (12), 4147, 2005 | 20 | 2005 |
