Numerical study of spallation phenomenon in an arc-jet environment RSC Davuluri, H Zhang, A Martin Journal of Thermophysics and Heat Transfer 30 (1), 32-41, 2016 | 71 | 2016 |
A data-driven RANS k-ω approach for modeling turbulent flows Z Li, H Zhang, SC Bailey, JB Hoagg, A Martin Journal of Computational Physics 345, 111-131, 2017 | 66* | 2017 |
Numerical and experimental analysis of spallation phenomena A Martin, SCC Bailey, F Panerai, RSC Davuluri, H Zhang, AR Vazsonyi, ... CEAS Space Journal 8, 229-236, 2016 | 35 | 2016 |
High temperature flow solver for aerothermodynamics problems H Zhang University of Kentucky, 2015 | 35 | 2015 |
Numerical simulation of an arc jet test section Ü Düzel, OM Schroeder, H Zhang, A Martin Journal of Thermophysics and Heat Transfer 34 (2), 393-403, 2020 | 29 | 2020 |
Towards optimal high-order compact schemes for simulating compressible flows H Zhang, F Zhang, C Xu Applied Mathematics and Computation 355, 221-237, 2019 | 28 | 2019 |
Effects of spalled particles thermal degradation on a hypersonic flow field environment RSC Davuluri, H Zhang, KA Tagavi, A Martin International Journal of Multiphase Flow 159, 104287, 2023 | 23 | 2023 |
An introduction to the derivation of surface balance equations without the excruciating pain A Martin, H Zhang, KA Tagavi International Journal of Heat and Mass Transfer 115, 992-999, 2017 | 23 | 2017 |
A simple extended compact nonlinear scheme with adaptive dissipation control H Zhang, F Zhang, J Liu, JM McDonough, C Xu Communications in Nonlinear Science and Numerical Simulation 84, 105191, 2020 | 19 | 2020 |
Simulation of flow-tube oxidation on the carbon preform of PICA H Zhang, H Weng, A Martin 52nd Aerospace Sciences Meeting, 1209, 2014 | 16 | 2014 |
Implementation of compressible porous–fluid coupling method in an aerodynamics and aeroacoustics code part I: Laminar flow Z Li, H Zhang, Y Liu, JM McDonough Applied Mathematics and Computation 364, 124682, 2020 | 15 | 2020 |
A multi-resolution weighted compact nonlinear scheme for hyperbolic conservation laws H Zhang, G Wang, F Zhang International Journal of Computational Fluid Dynamics 34 (3), 187-203, 2020 | 14 | 2020 |
A third‐order compact nonlinear scheme for compressible flow simulations Z Tian, G Wang, F Zhang, H Zhang International Journal for Numerical Methods in Fluids 92 (10), 1352-1367, 2020 | 10 | 2020 |
Preliminary numerical and experimental analysis of the spallation phenomenon A Martin, SCC Bailey, F Panerai, RSC Davuluri, AR Vazsonyi, H Zhang, ... European Symposium on Aerothermodynamics for Space Vehicles, 2015 | 7 | 2015 |
Numerical analysis of time accuracy of a primitive variable-based formulation of the conservative form of the governing equations for compressible flows H Zhang, A Martin, G Wang International Journal of Computational Fluid Dynamics 33 (1-2), 1-9, 2019 | 6 | 2019 |
Turbulence Simulation Using Direct Gradient Adaptive k-ω Model Z Li, H Zhang, J Hoagg, SC Bailey, A Martin 54th AIAA Aerospace Sciences Meeting, 0587, 2016 | 6 | 2016 |
An improved global-direction stencil based on the face-area-weighted centroid for the gradient reconstruction of unstructured finite volume methods LF Kong, YD Dong, W Liu, HB Zhang Chinese Physics B 29 (10), 100203, 2020 | 5 | 2020 |
An extending strategy based on TENO framework for hyperbolic conservation laws F Zhang, J Liu, H Zhang, C Xu arXiv preprint arXiv:1808.00037, 2018 | 4 | 2018 |
On the numerical overshoots of shock‐capturing schemes H Zhang, F Zhang International Journal for Numerical Methods in Fluids 93 (10), 3151-3159, 2021 | 3 | 2021 |
Extending the global-direction stencil with “face-area-weighted centroid” to unstructured finite volume discretization from integral form L Kong, Y Dong, W Liu, H Zhang Advances in Aerodynamics 2, 1-43, 2020 | 2 | 2020 |