[1] JI X, SHYY W, XU K*. A Gradient Compression-Based Compact High-Order Gas-Kinetic Scheme on 3D Hybrid Unstructured Meshes [J]. International Journal of Computational Fluid Dynamics, 2021, 35(7): 485-509.
英文文章
[31] Cai, J., Zhuang, Z., Cai, J., Zhang, F., Zhang, B. and Ji, X.* A Load-Adaptive and Large-Linear-Stroke Quasi-Zero-Stiffness Vibration Isolator Realized by a Novel Magnetic Negative Stiffness Mechanism. Mechanical Systems and Signal Processing, 2026.(TOP)(中科院一区)(Q1)
[30] Liu, H., Ji, X.*, Fu, Y. and Xu, K. A geometric multigrid-accelerated compact gas-kinetic scheme for fast convergence in high-speed flows on GPUs. Journal of Computational Physics, 2026, Accepted.(TOP)(中科院二区)(Q1)
[29] Liu, H., Ji, X.*, Mao, Y., Qian, Z. and Xu, K. A memory reduction compact gas kinetic scheme on 3D unstructured meshes. Computer Physics Communications, 2026, p.109981.(Q1)
[28] Zhang, H., Ji, X.*, Zhao, Y., Xu, K. Adaptive Reconstruction Method for Arbitrary High-Order Accuracy Using Discontinuity Feedback. Communications in Computational Physics, 2025, Accepted.(Q1)
[27] Liu, H., Yang, X., Zhang, C., Ji, X., Xu, K.* Implicit unified gas kinetic particle method for steady-state solution of multiscale phonon transport. Acta Mechanica Sinica, 2025, Accepted.(Q1)
[26] Liu, H., Yang, X., Zhang, C., Ji, X., Xu, K.* Unified gas-kinetic wave-particle method for multiscale phonon transport. PHYSICAL REVIEW E 112, 065304 (2025).(Q1)
[25] Zhang, J., Ji, X., Xu, K.* Treatment of Wall Boundary Conditions in High-Order Compact Gas-Kinetic Schemes. Journal of Computational Physics, 2025, Accepted.(TOP)(中科院二区)(Q1)
[24] Gao, X., Ji, X.*, Liu, H., Chen, G. A Two-Temperature Gas-Kinetic Scheme for Hypersonic Non-Equilibrium Flow Computations. Physics of Fluids, 2025, 37 (10): 106138.(Q1)
[23] Liu, H., Ji, X., Mao, Y., Ding, Y. and Xu, K. A Compact Gas-Kinetic Scheme with Scalable hp Multigrid Acceleration for Steady-State Computation on 3D Unstructured Meshes. Computer Physics Communications, 2025, p.109820.(Q1)
[22] Wang, Y., Ji, X., and Pan, L.* An efficient and robust high-order compact ALE gas-kinetic scheme for unstructured meshes. Journal of Computational Physics, 2025, Accepted.(TOP)(中科院二区)(Q1)
[21] Li, C, Ji, X, Xu, K*, Wang, L. The Effects of Spatial Reconstruction and Flux Solver on the Performance of High-Order Finite-Volume Compressible Flow Solvers. Communications in Computational Physics, 2025, 38(1), 37–73(Q1)
[20] Li X, Niu X, Liu Z, Jiang L, Ji X, Chen G*; A hybrid graph neural network-based framework for aerothermal prediction on hypersonic vehicles. Physics of Fluids. 2025 Jul; 37 (7): 077163.(Q1)
[19] Zhang H, Ji X*, Zhao Y, et al. A robustness-enhanced reconstruction based on discontinuity feedback factor for high-order finite volume scheme. Journal of Scientific Computing. 2024 Oct;101(1):20.(TOP)(中科院二区)(Q1)
[18] Wei, Y, Cao, J, Ji, X, et al. Adaptive wave-particle decomposition in UGKWP method for high-speed flow simulations. Advances in Aerodynamics [J]. 5, 25 (2023).
[17] JI X, ZHAO F, SHYY W, et al. Two-step multi-resolution reconstruction-based compact gas-kinetic scheme on tetrahedral mesh [J]. Journal of Computational Physics. 2024, 497:112590.(TOP)(中科院二区)(Q1)
[16] XIE Q, JI X, QIU Z, et al. High-order spectral difference gas-kinetic schemes for Euler and Navier-Stokes equations [J] East Asian Journal on Applied Mathematics, 2023, 13 (3), 499-523.(Q1)
[15] ZHANG Y, JI X, XU K*. A high-order compact gas-kinetic scheme in a rotating coordinate frame and on sliding mesh [J]. International Journal of Computational Fluid Dynamics, 2023, Accept.
[14] ZHAO F, JI X, SHYY W, et al. Direct modeling for computational fluid dynamics and the construction of high-order compact scheme for compressible flow simulations [J]. Journal of Computational Physics, 2023.(TOP)(中科院二区)(Q1)
[13] YANG X, LIU C, JI X, et al. Unified Gas-Kinetic Wave-Particle Methods VI: Disperse Dilute Gas-Particle Multiphase Flow [J]. Communications in Computational Physics, 2022, 31(3):669.(Q1)
[12] JI X, SHYY W, XU K*. A p-multigrid compact gas-kinetic scheme for steady-state acceleration [J]. Computers & Fluids, 2022, 241: 105489.
[11] YANG X, JI X, SHYY W, et al. Comparison of the performance of high-order schemes based on the gas-kinetic and HLLC fluxes [J]. Journal of Computational Physics, 2022, 448: 110706.(TOP)(中科院二区)(Q1)
[10] ZHAO F, JI X, SHYY W, et al. A compact high-order gas-kinetic scheme on unstructured mesh for acoustic and shock wave computations [J]. Journal of Computational Physics, 2021: 110812.(TOP)(中科院二区)(Q1)
[9] JI X, SHYY W, XU K*. A Gradient Compression-Based Compact High-Order Gas-Kinetic Scheme on 3D Hybrid Unstructured Meshes [J]. International Journal of Computational Fluid Dynamics, 2021, 35(7): 485-509.
[8] JI X, ZHAO F, SHYY W, et al. Compact High-Order Gas-Kinetic Scheme for Three-Dimensional Flow Simulations [J]. AIAA Journal, 2021: 1-18.(Q1)
[7] ZHAO F, JI X, SHYY W, et al. An acoustic and shock wave capturing compact high-order gas-kinetic scheme with spectral-like resolution [J]. International Journal of Computational Fluid Dynamics, 2020, 34(10): 731-56.
[6] JI X, ZHAO F, SHYY W, et al. A HWENO reconstruction based high-order compact gas-kinetic scheme on unstructured mesh [J]. Journal of Computational Physics, 2020, 410: 109367.(TOP)(中科院二区)(Q1)
[5] JI X, XU K*. Performance enhancement for high-order gas-kinetic scheme based on WENO-adaptive-order reconstruction [J]. Communications in Computational Physics, 2020, 28(2), 539-590.(Q1)
[4] ZHAO F, JI X, SHYY W, et al. Compact higher-order gas-kinetic schemes with spectral-like resolution for compressible flow simulations [J]. Advances in Aerodynamics, 2019, 1(1): 1-34.
[3] JI X, PAN L, SHYY W, et al. A compact fourth-order gas-kinetic scheme for the Euler and Navier–Stokes equations [J]. Journal of Computational Physics, 2018, 372: 446-72.(TOP)(中科院二区)(Q1)
[2] JI X, ZHAO F, SHYY W, et al. A family of high-order gas-kinetic schemes and its comparison with Riemann solver based high-order methods [J]. Journal of Computational Physics, 2018, 356: 150-73.(TOP)(中科院二区)(Q1)
[1] SHI M, JI X, FENG S, et al. Self-propelled hovercraft based on cold Leidenfrost phenomenon [J]. Scientific reports, 2016, 6(1): 1-7.(Q1)
[2] 水涌涛,张昱煜,姬兴,等.基于高阶气体动理学格式的高速流动数值模拟[J].飞行力学,2024,42(04):1-6.DOI:10.13645/j.cnki.f.d.2024.
[1] 苑宗敬*,姬兴,陈刚. 波动翼非定常流场IB-LBM数值研究[J]. 气体物理,2017,2(1):39-47. DOI:10.19527/j.cnki.2096-1642.2017.01.005.
JI X. High-order non-compact and compact gas-kinetic schemes - Rare & Special e-Zone (hkust.edu.hk)
Hong Kong University of Science and Technology (Hong Kong), 2019.