Ph.D. thesis
  1. Lin Fu. Numerical methods for computational fluid dynamics - a new ENO paradigm and a new domain decomposition method, Technische Universität München, Germany, Oct. 2nd, 2017 (Summa cum laude, passed with the highest distinction).
Patent
  1. Method and system for generating a mesh, Xiangyu Hu, Lin Fu (the first author as a Ph.D. student and the major contributor), Luhui Han, Nikolaus Adams, EP3255611 (Europe),US20190304180A1 (USA), December 13, 2017.
Journal papers
(Arch. Comput. Methods Eng. 1, Proc. Natl. Acad. Sci. U.S.A. 1, J. Fluid Mech. 14, Phys. Rev. Fluids 9, J. Comput. Phys. 21, Comput. Methods. Appl. Mech. Eng. 9, Comput. Phys. Commun. 8, Commun. Comput. Phys. 8, J. Sci. Comput. 8, Int. J. Multiph. Flow 1, Int. J. Heat Fluid Flow 2, Comput. Fluids 1, AIAA J. 2, Acta Mech. Sin. 1, Theor. Comput. Fluid Dyn. 1, Eng. Comput. 1, Theor. App. Mech. Lett. 1)
  1. Liang, Tian; Shyy, Wei; Fu, Lin; Efficient arbitrary-high-order TENO schemes with local adaptive dissipation for compressible flow simulation on unstructured meshes, Journal of Scientific Computing, Accepted, 2025.
  2. Chen, Xianliang; Gan, Jianping; Fu, Lin; Mean temperature-velocity relation and a new temperature wall model for compressible laminar and turbulent flows, Journal of Fluid Mechanics, 1009 (2025): A39.
  3. Wu, Buchen; Fu, Lin; An implicit moving-least-squares immersed boundary method for high-fidelity fluid-structure interaction simulations, Journal of Computational Physics, 530 (2025): 113913.
  4. Yuan, Mingduo; Gao, Tianrun; Fu, Lin; A diffuse-interface smoothed particle hydrodynamics method for compressible multiphase flows, Journal of Computational Physics, 524 (2025): 113717.
  5. Wu, Buchen; Liu, Yaguang; Fu, Lin; One-side diffuse-interface immersed boundary method for compressible flows, Journal of Computational Physics, 523 (2025): 113667.
  6. Huang, Haohan; Li, Xinliang; Fu, Lin; A new high-order RKDG method based on the TENO-THINC scheme for shock-capturing, Journal of Computational Physics, 520 (2025): 113459.
  7. Ying, Anjia; Chen, Xianliang; Li, Zhigang; Fu, Lin; Optimisation and modelling of eddy viscosity in the resolvent analysis of turbulent channel flows, Journal of Fluid Mechanics, 1001 (2024): A20.
  8. Cheng, Cheng; Fu, Lin; A Reynolds analogy model for compressible wall turbulence, Journal of Fluid Mechanics, 999 (2024): A20.
  9. Cheng, Cheng; Fu, Lin; Comparisons between the first- and second-order spectral stochastic estimations in investigating the multiphysics couplings for a supersonic turbulent channel flow, Physical Review Fluids, 9 (2024): 104607.
  10. Liang, Tian; Fu, Lin; A novel finite-difference converged ENO scheme for steady-state simulations of Euler equations, Journal of Computational Physics, 519 (2024): 113386.
  11. Li, Qichao; Fu, Lin; A family of TENOA-THINC-MOOD schemes based on diffuse-interface method for compressible multiphase flows, Journal of Computational Physics, 519 (2024): 113375.
  12. Ying, Anjia; Li, Zhigang; Fu, Lin; The generalised resolvent-based turbulence estimation with arbitrarily sampled measurements in time, Journal of Fluid Mechanics, 998 (2024): A3.
  13. Liang, Tian; Fu, Lin; A new class of very-high-order finite difference TENO schemes with discontinuity-resolving property for compressible Euler equations, Communications in Computational Physics, 36 (2024): 618-650.
  14. Gao, Tianrun; Fu, Lin; A three-dimensional meshless fluid-shell interaction framework based on smoothed particle hydrodynamics coupled with semi-meshless thin shell, Computer Methods in Applied Mechanics and Engineering, 429 (2024): 117179.
  15. Chen, Kuangxu; Fu, Lin; Efficient dimension-by-dimension adaptive TENO-based limiter and troubled-cell indicator for nodal-based high-order spectral difference method, Journal of Computational Physics, 513 (2024): 113156.
  16. Cheng, Cheng; Fu, Lin; Mean temperature scalings in compressible wall turbulence, Physical Review Fluids, 9 (2024): 054610.
  17. Liang, Tian; Fu, Lin; A new high-order shock-capturing TENO scheme combined with skew-symmetric-splitting method for compressible gas dynamics and turbulence simulation, Computer Physics Communications, 302 (2024): 10923.
  18. Chen, Xianliang; Gan, Jianping; Fu, Lin; An improved Baldwin-Lomax algebraic wall model for high-speed canonical turbulent boundary layers using established scalings, Journal of Fluid Mechanics, 987 (2024): A7.
  19. Liang, Tian; Cheng, Cheng; Fu, Lin; Multi-scale analysis of the space-time properties in incompressible wall-bounded turbulence, Physical Review Fluids, 9 (2024): 054606.
  20. Liang, Tian; Fu, Lin; Finite-volume TENO scheme with a new cell-interface flux evaluation strategy for unstructured meshes, Communications in Computational Physics, 35 (2024): 938-972.
  21. Zhu, Wenkai; Chen, Xianliang; Fu, Lin; Resolvent analyses of incompressible turbulent channel, pipe and boundary-layer flows, International Journal of Heat and Fluid Flow, 106 (2024): 109331.
  22. Bai, Tianyi; Cheng, Cheng; Fu, Lin; Investigation on the inclination angles of wall-attached eddies for streamwise velocity and temperature fields in compressible turbulent channel flows, Physical Review Fluids, 9 (2024): 034611.
  23. Cheng, Cheng; Fu, Lin; On the streamwise velocity, temperature and passive scalar fields in compressible turbulent channel flows: a viewpoint from multi-physics couplings, Journal of Fluid Mechanics, 983 (2024): A38.
  24. Gao, Tianrun; Qiu, Huihe; Fu, Lin; A semi-meshless Lagrangian finite-volume framework based on Voronoi diagram for general elastoplastic Reissner-Mindlin shell, Journal of Computational Physics, 501 (2024): 112802.
  25. Huang, Haohan; Fu, Lin; A new troubled cell indicator and a new limiter based on TENO schemes for RKDG methods, Computer Methods in Applied Mechanics and Engineering, 421 (2024): 116795.
  26. Zheng, Qinmin; Li, Tianyi; Ma, Benteng; Fu, Lin; Li, Xiaomeng; High-fidelity Reconstruction of Large-area Damaged Turbulent Fields with Physically-constrained Generative Adversarial Network, Physical Review Fluids, 9 (2024): 024608, Editors’ Suggestion.
  27. Li, Qichao; Lv, Yu; Fu, Lin; A high-order diffuse-interface method with TENO-THINC scheme for compressible multiphase flows, International Journal of Multiphase Flow, 173 (2024): 104732.
  28. Cheng, Cheng; Chen, Xianliang; Zhu, Wenkai; Shyy, Wei; Fu, Lin; Progress in physical modeling of compressible wall-bounded turbulent flows, Acta Mechanica Sinica, 40 (2024): 323663, Cover Page on Acta Mechanica Sinica.
  29. Liang, Tian; Fu, Lin; A new type of non-polynomial based TENO scheme for hyperbolic conservation laws, Journal of Computational Physics, 497 (2024): 112618.
  30. Bai, Tianyi; Cheng, Cheng; Griffin, Kevin P.; Li, Xinliang; Fu, Lin; Study of the vortex structure in compressible wall-bounded turbulence, Physical Review Fluids, 8 (2023): 124603.
  31. Ying, Anjia; Liang, Tian; Li, Zhigang; Fu, Lin; A resolvent-based prediction framework for incompressible turbulent channel flow with limited measurements, Journal of Fluid Mechanics, 976 (2023): A31.
  32. Chen, Xianliang; Cheng, Cheng; Gan, Jianping; Fu, Lin; Study of the linear models in estimating coherent velocity and temperature structures for compressible turbulent channel flows, Journal of Fluid Mechanics, 973 (2023): A36.
  33. Cheng, Cheng; Shyy, Wei; Fu, Lin; Momentum and heat flux events in compressible turbulent channel flows, Physical Review Fluids, 8 (2023): 094602.
  34. Takagi, Shinichi; Wakimura, Hiro; Fu, Lin; Xiao, Feng; High-order low-dissipation shock-resolving TENO-THINC schemes for hyperbolic conservation laws, Communications in Computational Physics, 34 (2023): 1043-1078.
  35. Griffin, Kevin P.; Fu, Lin; Moin, Parviz; Near-wall model for compressible turbulent boundary layers based on an inverse velocity transformation, Journal of Fluid Mechanics, 970 (2023): A36.
  36. Gao, Tianrun; Liang, Tian; Fu, Lin; A new smoothed particle hydrodynamics method based on high-order moving-least-square targeted essentially non-oscillatory scheme for compressible flows, Journal of Computational Physics, 489 (2023): 112270.
  37. Calvo, Manuel; Fu, Lin; Montijano, Juan Ignacio; Randez, Luis; Singly Time–Accurate and highly–Stable Explicit (STASE) operators for the numerical solution of stiff differential equations, Journal of Scientific Computing, 96 (2023): 17.
  38. Bai, Tianyi; Cheng, Cheng; Fu, Lin; Effects of mean shear on the vortex identification and the orientation statistics, Theoretical and Applied Mechanics Letters, 13 (2023): 100454.
  39. Cheng, Cheng; Fu, Lin; Linear-model-based study of the coupling between velocity and temperature fields in compressible turbulent channel flows, Journal of Fluid Mechanics, 964 (2023): A15.
  40. Ji, Zhe; Liang, Tian; Fu, Lin; High-order finite-volume TENO schemes with dual ENO-like stencil selection for unstructured meshes, Journal of Scientific Computing, 95 (2023): 76.
  41. Cheng, Cheng; Fu, Lin; A scale-based study of the Reynolds number scaling for the near-wall streamwise turbulence intensity in wall turbulence, International Journal of Heat and Fluid Flow, 101 (2023): 109136.
  42. Chen, Xianliang; Cheng, Cheng; Fu, Lin; Gan, Jianping; Linear response analysis of supersonic turbulent channel flows with a large parameter space, Journal of Fluid Mechanics, 962 (2023): A7.
  43. Huang, Haohang; Liang, Tian; Fu, Lin; A five-point TENO scheme with adaptive dissipation based on a new scale sensor, Communications in Computational Physics, 33 (2023): 1106-1131.
  44. Fu, Lin; Review of the high-order TENO schemes for compressible gas dynamics and turbulence, Archives of Computational Methods in Engineering, 30 (2023): 2493-2526.
  45. Li, Yue; Fu, Lin; Adams, Nikolaus; A Family of Fast Multi-resolution ENO Schemes for Compressible Flows, Journal of Scientific Computing, 94 (2023): 44.
  46. Tsoutsanis, Panagiotis; Nogueira, Xesus; Fu, Lin; A short note on a 3D spectral analysis for turbulent flows on unstructured meshes, Journal of Computational Physics, 474 (2023): 111804.
  47. Gao, Tianrun; Fu, Lin; A new particle shifting technique for SPH methods based on Voronoi diagram and volume compensation, Computer Methods in Applied Mechanics and Engineering, 404 (2023): 115788.
  48. Gao, Tianrun; Qiu, Huihe; Fu, Lin; Multi-level adaptive particle refinement method with large refinement scale ratio and new free-surface detection algorithm for complex fluid-structure interaction problems, Journal of Computational Physics, 473 (2023): 111762.
  49. Cheng, Cheng; Fu, Lin; Large-scale motions and self-similar structures in compressible turbulent channel flows, Physical Review Fluids, 7 (2022): 114604.
  50. Fu, Lin; Liang, Tian; A new adaptation strategy for multi-resolution method, Journal of Scientific Computing, 93 (2022): 43.
  51. Cheng, Cheng; Shyy, Wei; Fu, Lin; Streamwise inclination angle of wall-attached eddies in turbulent channel flows, Journal of Fluid Mechanics, 946 (2022): A49.
  52. Liang, Tian; Xiao, Feng; Shyy, Wei; Fu, Lin; A fifth-order low-dissipation discontinuity-resolving TENO scheme for compressible flow simulation, Journal of Computational Physics, 467 (2022): 111465.
  53. Gao, Tianrun; Qiu, Huihe; Fu, Lin; A Block-based Adaptive Particle Refinement SPH Method for Fluid-Structure Interaction Problems, Computer Methods in Applied Mechanics and Engineering, 399C (2022): 115356.
  54. Ji, Zhe; Liang, Tian; Fu, Lin; A class of new high-order finite-volume TENO schemes for hyperbolic conservation laws with unstructured meshes, Journal of Scientific Computing, 92 (2022): 61.
  55. Antoniadis, Antonis F.; Drikakis, Dimitris; Farmakis, Pericles S.; Fu, Lin; Kokkinakis, Ioannis; Nogueira, Xesus; Silva, Paulo A.S.F.; Skote, Martin; Titarev, Vladimir; Tsoutsanis, Panagiotis; UCNS3D: An open-source high-order finite-volume unstructured CFD solver, Computer Physics Communications, 279 (2022): 108453.
  56. Cheng, Cheng; Fu, Lin; Consistency between the attached eddy model and the inner-outer interaction model: a study of streamwise wall-shear stress fluctuations in a turbulent channel flow, Journal of Fluid Mechanics (JFM Rapids), 942 (2022): R9.
  57. Bai, Tianyi; Griffin, Kevin Patrick; Fu, Lin; Compressible Velocity Transformations for Various Noncanonical Wall-Bounded Turbulent Flows, AIAA Journal, 60 (2022): 4325-4337.
  58. Takagi, Shinichi; Fu, Lin; Wakimura, Hiro; Xiao, Feng; A novel high-order low-dissipation TENO-THINC scheme for hyperbolic conservation laws, Journal of Computational Physics, 452 (2022): 110899.
  59. Fu, Lin; An efficient low-dissipation high-order TENO scheme for MHD flows, Journal of Scientific Computing, 90 (2022): 55.
  60. Fu, Lin; Very-high-order TENO schemes with adaptive accuracy order and adaptive dissipation control, Computer Methods in Applied Mechanics and Engineering, 387C (2021): 114193.
  61. Griffin, Kevin Patrick; Fu, Lin; Moin, Parviz; Velocity transformation for compressible wall-bounded turbulent flows with and without heat transfer, Proceedings of the National Academy of Sciences of the United States of America (PNAS), 118 (2021): e2111144118.
  62. Fu, Lin; Bose, Sanjeeb; Moin, Parviz; Prediction of aerothermal characteristics of a generic hypersonic inlet flow, Theoretical and Computational Fluid Dynamics, 36 (2022): 345-368.
  63. Griffin, Kevin Patrick; Fu, Lin; Moin, Parviz; General method for determining the boundary layer thickness in nonequilibrium flows, Physical Review Fluids, 6 (2021): 024608 .
  64. Ji, Zhe; Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A Feature-aware SPH for Isotropic Unstructured Mesh Generation, Computer Methods in Applied Mechanics and Engineering, 375 (2021): 113634.
  65. Li, Yue; Fu, Lin; Adams, Nikolaus; A low-dissipation shock-capturing framework with flexible nonlinear dissipation control, Journal of Computational Physics, 428 (2021): 109960.
  66. Fu, Lin; Karp, Michael; Bose, Sanjeeb; Moin, Parviz; Urzay, Javier; Shock-induced heating and transition to turbulence in a hypersonic boundary layer, Journal of Fluid Mechanics, 909 (2021): A8.
  67. Bassenne, Maxime; Fu, Lin; Mani, Ali; Time-Accurate and highly-Stable Explicit operators for stiff differential equations, Journal of Computational Physics, 424 (2021): 109847.
  68. Renzo, Mario Di; Fu, Lin; Urzay, Javier; HTR solver: An open-source exascale-oriented task-based multi-GPU high-order code for hypersonic aerothermodynamics, Computer Physics Communications, 255 (2020): 107262.
  69. Ji, Zhe; Fu, Lin (co-first-author); Hu, Xiangyu; Adams, Nikolaus; A Consistent Parallel Isotropic Unstructured Mesh Generation Method based on Multi-phase SPH, Computer Methods in Applied Mechanics and Engineering, 363 (2020): 112881.
  70. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; Adaptive anisotropic unstructured mesh generation method based on fluid relaxation analogy, Communications in Computational Physics, 27 (2020): 1275-1308.​
  71. Fu, Lin; A very-high-order TENO scheme for all-speed gas dynamics and turbulence, Computer Physics Communications, 244 (2019): 117-131.
  72. Fu, Lin; Tang, Qi; High-order low-dissipation targeted ENO schemes for ideal magnetohydrodynamics, Journal of Scientific Computing, 80 (2019): 692-716.
  73. Fu, Lin; Han, Luhui; Hu, Xiangyu; Adams, Nikolaus; An isotropic unstructured mesh generation method based on a fluid relaxation analogy, Computer Methods in Applied Mechanics and Engineering, 350C (2019): 396-431.
  74. Ji, Zhe; Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A Lagrangian Inertial Centroidal Voronoi Particle method for dynamic load balancing in particle-based simulations, Computer Physics Communications, 239 (2019): 53-63.
  75. Fu, Lin; A hybrid method with TENO based discontinuity indicator for hyperbolic conservation laws, Communications in Computational Physics, 26 (2019): 973-1007.
  76. Fu, Lin; Ji, Zhe; Hu, Xiangyu; Adams, Nikolaus; Parallel fast-neighbor-searching and communication strategy for particle-based methods, Engineering Computations, 36 (2019): 899-929.
  77. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; Improved Five- and Six-Point Targeted Essentially Nonoscillatory Schemes with Adaptive Dissipation, AIAA Journal, 57 (2019): 1143-1158.
  78. Fu, Lin; A low-dissipation finite-volume method based on a new TENO shock-capturing scheme, Computer Physics Communications, 235 (2019): 25-39.
  79. Ji, Zhe; Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A new multi-resolution parallel framework for SPH, Computer Methods in Applied Mechanics and Engineering, 346 (2019): 1156-1178.
  80. Fu, Lin; Ji, Zhe ; An optimal particle setup method with Centroidal Voronoi Particle dynamics, Computer Physics Communications, 234 (2019): 72-92.
  81. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A targeted ENO scheme as implicit model for turbulent and genuine subgrid scales, Communications in Computational Physics, 26 (2019): 311-345.
  82. Dong, Haibo; Fu, Lin; Zhang, Fan; Liu, Yu; Liu, Jun; Detonation simulations with a fifth-order TENO scheme, Communications in Computational Physics, 25 (2019): 1357-1393.
  83. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A new class of adaptive high-order targeted ENO schemes for hyperbolic conservation laws, Journal of Computational Physics, 374 (2018): 724-751.
  84. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; Single-step reinitialization and extending algorithms for level-set based multi-phase flow simulations, Computer Physics Communications, 221 (2017): 63-80.
  85. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; Targeted ENO schemes with tailored resolution property for hyperbolic conservation laws, Journal of Computational Physics, 349 (2017): 97-121.
  86. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A physics-motivated Centroidal Voronoi Particle domain decomposition method, Journal of Computational Physics, 335 (2017): 718-735.
  87. Fu, Lin; Litvinov, Sergej; Hu, Xiangyu; Adams, Nikolaus; A novel partitioning method for block-structured adaptive meshes, Journal of Computational Physics, 341 (2017): 447-473.
  88. Fu, Lin; Hu, Xiangyu; Adams, Nikolaus; A family of high-order targeted ENO schemes for compressible-fluid simulations, Journal of Computational Physics, 305 (2016): 333-359.
  89. Fu, Lin; Gao, Zhenghong; Xu, Kan; Xu, Fang; A multi-block viscous flow solver based on GPU parallel methodology, Computers and Fluids 95 (2014): 19-39.
  90. Fu, Lin; Gao, Zhenghong; Zuo, Yingtao; Application on MLP high order reconstruction scheme, Journal of Aerospace Power, 29 (2014): 2321–2330.
  91. Fu, Lin; Gao, Zhenghong; Zuo, Yingtao; High order WENO scheme based on HLL-HLLC solver and its application, Chinese Journal of Computational Mechanics, 31 (2014): 128–134.
  92. Fu, Lin; Gao, Zhenghong; Zhang, Xiaodong; Construction and application research of HLL-HLLC scheme, Acta Aerodynamica Sinica, 32 (2014): 116-122.
Archival publications
  1. Griffin, Kevin Patrick; Fu, Lin; Moin, Parviz; Near-wall model for compressible turbulent boundary layers based on an inverse velocity transformation, Annual Research Briefs 2022, Center for Turbulence Research, Stanford University.
  2. Griffin, Kevin Patrick; Fu, Lin; Moin, Parviz; The effect of compressibility on grid-point and time-step requirements for simulations of wall-bounded turbulent flows, Annual Research Briefs 2021, Center for Turbulence Research, Stanford University.
  3. Fu, Lin; Griffin, Kevin Patrick; High-order TENO scheme for high-speed flows, Annual Research Briefs 2021, Center for Turbulence Research, Stanford University.
  4. Griffin, Kevin Patrick; Fu, Lin; Moin, Parviz; Incorporating non-equilibrium effects in an ODE-based wall model, Annual Research Briefs 2020, Center for Turbulence Research, Stanford University.
  5. Fu, Lin; Bose, Sanjeeb; Moin, Parviz; Wall-modeled LES of three-dimensional intersecting shock wave/turbulent boundary-layer interactions, Annual Research Briefs 2020, Center for Turbulence Research, Stanford University.
  6. Fu, Lin; Karp, Michael; Bose, Sanjeeb; Moin, Parviz; Urzay, Javier; Turbulence statistics in a high Mach number boundary layer downstream of an incident shock wave, Annual Research Briefs 2019, Center for Turbulence Research, Stanford University.​
  7. Fu, Lin; Karp, Michael; Bose, Sanjeeb; Moin, Parviz; Urzay, Javier; Equilibrium wall-modeled LES of shock-induced aerodynamic heating in hypersonic boundary layers, Annual Research Briefs 2018, Center for Turbulence Research, Stanford University.
  8. Gao, Xiangyu; Buchmeier, Jonas; Bermejo-Moreno, Ivan; Larsson, Johan; Fu, Lin; Lele, Sanjiva; Scalar mixing under shock/turbulence interaction: DNS, statistical and geometric analyses, Proceedings of the Summer Program 2018, Center for Turbulence Research, Stanford University.