| Uncovering turbulent plasma dynamics via deep learning from partial observations A Mathews, M Francisquez, JW Hughes, DR Hatch, B Zhu, BN Rogers Physical Review E 104 (2), 025205, 2021 | 87* | 2021 |
| Simulations of tokamak boundary plasma turbulence transport in setting the divertor heat flux width XQ Xu, NM Li, ZY Li, B Chen, TY Xia, TF Tang, B Zhu, VS Chan Nuclear Fusion 59 (12), 126039, 2019 | 73 | 2019 |
| GDB: A global 3D two-fluid model of plasma turbulence and transport in the tokamak edge B Zhu, M Francisquez, BN Rogers Computer Physics Communications 232 (11), 46-58, 2018 | 62 | 2018 |
| Global 3D two-fluid simulations of the tokamak edge region: Turbulence, transport, profile evolution, and spontaneous E× B rotation B Zhu, M Francisquez, BN Rogers Physics of Plasmas 24 (5), 2017 | 53 | 2017 |
| Electric field and turbulence in global Braginskii simulations across the ASDEX Upgrade edge and scrape-off layer W Zholobenko, T Body, P Manz, A Stegmeir, B Zhu, M Griener, ... Plasma Physics and Controlled Fusion 63 (3), 034001, 2021 | 48 | 2021 |
| Drift reduced Landau fluid model for magnetized plasma turbulence simulations in BOUT++ framework B Zhu, H Seto, X Xu, M Yagi Computer Physics Communications 267 (10), 108079, 2021 | 35 | 2021 |
| Machine learning surrogate models for Landau fluid closure C Ma, B Zhu, XQ Xu, W Wang Physics of Plasmas 27 (4), 2020 | 34 | 2020 |
| DIII-D research advancing the physics basis for optimizing the tokamak approach to fusion energy ME Fenstermacher, J Abbate, S Abe, T Abrams, M Adams, B Adamson, ... Nuclear Fusion 62 (4), 042024, 2022 | 29 | 2022 |
| Global 3D Braginskii simulations of the tokamak edge region of IWL discharges M Francisquez, B Zhu, BN Rogers Nuclear Fusion 57 (11), 116049, 2017 | 24 | 2017 |
| Deep learning surrogate model for kinetic Landau-fluid closure with collision L Wang, XQ Xu, B Zhu, C Ma, Y Lei AIP Advances 10 (7), 2020 | 23 | 2020 |
| Thermal dynamics in the flux‐coordinate independent turbulence code GRILLIX W Zholobenko, A Stegmeir, T Body, A Ross, P Manz, O Maj, D Coster, ... Contributions to Plasma Physics 60 (5-6), e201900131, 2020 | 19 | 2020 |
| Fluid and gyrokinetic turbulence in open field-line, helical plasmas M Francisquez, TN Bernard, B Zhu, A Hakim, BN Rogers, GW Hammett Physics of Plasmas 27 (8), 2020 | 16 | 2020 |
| A Landau-fluid closure for arbitrary frequency response L Wang, B Zhu, X Xu, B Li AIP Advances 9 (1), 2019 | 16 | 2019 |
| Gyrokinetic theory of slab universal modes and the non-existence of the gradient drift coupling (GDC) instability BN Rogers, B Zhu, M Francisquez Physics of Plasmas 25 (5), 2018 | 14 | 2018 |
| Data-driven model for divertor plasma detachment prediction B Zhu, M Zhao, H Bhatia, X Xu, PT Bremer, W Meyer, N Li, T Rognlien Journal of Plasma Physics 88 (5), 895880504, 2022 | 12 | 2022 |
| Electromagnetic turbulence simulation of tokamak edge plasma dynamics and divertor heat load during thermal quench B Zhu, X Xu, XZ Tang Nuclear Fusion 63 (8), 086027, 2023 | 11 | 2023 |
| Numerical modeling of pedestal stability and broadband turbulence of wide-pedestal QH-mode plasmas on DIII-D Z Li, X Chen, CM Muscatello, KH Burrell, X Xu, B Zhu, R Hong, ... Nuclear Fusion 62 (7), 076033, 2022 | 11 | 2022 |
| Up–down symmetry breaking in global tokamak edge simulations B Zhu, M Francisquez, BN Rogers Nuclear Fusion 58 (10), 106039, 2018 | 10 | 2018 |
| Multigrid treatment of implicit continuum diffusion M Francisquez, B Zhu, BN Rogers Computer Physics Communications 236 (3), 104-117, 2019 | 6 | 2019 |
| Simulations of turbulence, its suppression and profile evolution across the edge and scrape-off layer of ASDEX upgrade tokamak W Zholobenko, T Body, A Stegmeir, M Griener, B Zhu, P Manz, D Coster, ... Nucl. Fusion, 2021 | 3 | 2021 |