彭程
Professor
Visit:
Personal Information:
  • Name (Pinyin):
    Peng Cheng
  • Date of Employment:
    2020-12-14
  • School/Department:
    机械工程学院
  • Administrative Position:
    教工
  • Education Level:
    With Certificate of Graduation for Doctorate Study
  • Business Address:
    山东大学千佛山校区8号楼416-2
  • Gender:
    Male
  • Degree:
    Doctoral Degree in Philosophy
  • Status:
    Employed
  • Alma Mater:
    University of Delaware
  • Supervisor of Doctorate Candidates
  • Supervisor of Master's Candidates
Discipline:
Engineering Mechanics;
Honors and Titles:

2019-07-24    ICMMES CSRC Award, 16th ICMMES;
Education
  • 2006-9 — 2010-7
    西安交通大学
    能源动力系统及自动化
    工学学士
  • 2010-9 — 2013-7
    中国科学院大学
    工程热物理
    Master's Degree in Engineering
  • 2013-7 — 2018-5
    University of Delaware
    Mechanical Engineering
    Doctoral Degree in Philosophy
Working-Papers

Fluid Mechanics: Turbulent flows, multiphase flows, particle-laden flows, Computational Fluid Dynamics, direct numerical simulations, lattice Boltzmann approaches, immersed boundary methods, etc.

Publication
Research direction

1. Fluid Mechanics

Papers

1. 王帅. Analysis on the force evaluation by the momentum exchange method and a localized refilling scheme for the lattice Boltzmann method .Computers & Mathematics with Applications.2025,183 :180-199

2. 孙欣宇. Dynamics and acoustics of bubbles detached from non-rigid orifices .PHYSICS OF FLUIDS.2025,37 (1)

3. 王贵超. Estimation of the dissipation rate of turbulent kinetic energy: A review .Chemical Engineering Science.2021 ( 229)

4. 王贵超. LBM study of aggregation of monosized spherical particles in homogeneous isotropic turbulence .Chemical Engineering Science.2019,201 :201-211

5. Zhang, Zehua. A highly-efficient locally encoded boundary scheme for lattice Boltzmann method on GPU .COMPUTER PHYSICS COMMUNICATIONS Journal.2024,298

6. Karzhaubayev, Kairzhan. An immersed boundary method-discrete unified gas kinetic scheme simulation of particle-laden turbulent channel flow on a nonuniform orthogonal mesh .INTERNATIONAL JOURNAL FOR NUMERICAL METHODS IN FLUIDS.2023

7. 彭程. Preferential accumulation of finite-size particles in near-wall streaks .JOURNAL OF FLUID MECHANICS.2024,980

8. 彭程. Lattice Boltzmann simulations of homogeneous shear turbulence laden with finite-size particles .Computers & Mathematics with Applications.2024,154 :65-77

9. Shen, Jie. Influence of particle-fluid density ratio on the dynamics of finite-size particles in homogeneous isotropic turbulent flows .Physical Review E.2021,104 (2):025109

10. 彭程. Direct numerical simulation of homogeneous shear turbulence subject to a shear periodic boundary with the lattice Boltzmann method .Computers & Mathematics with Applications.2023,146 :192-199

11. 彭程. Parameterization of turbulence modulation by finite-size solid particles in forced homogeneous isotropic turbulence .JOURNAL OF FLUID MECHANICS.2023,963

12. Soomro, Muzammil. Fugacity-based lattice Boltzmann method for multicomponent multiphase systems .Physical Review E.2023,107 (1)

13. Shen, Jie. Turbulence modulation by finite-size particles of different diameters and particle-fluid density ratios in homogeneous isotropic turbulence .JOURNAL OF TURBULENCE.2022,23 (8):433-453

14. Dong, Zhi-Qiang. A systematic study of hidden errors in the bounce-back scheme and their various effects in the lattice Boltzmann simulation of viscous flows .PHYSICS OF FLUIDS.2022,34 (9)

15. Wang, Zhicheng. Two pressure boundary conditions for multi-component multiphase flow simulations using the pseudo-potential lattice Boltzmann model .Computers and Fluids.2022,248

16. 彭程. Fluid-wall interactions in pseudopotential lattice Boltzmann models .PHYSICAL REVIEW E.2021 (3):1

17. Hu, Liangquan. Direct Numerical Simulation of Sediment Transport in Turbulent Open Channel Flow Using the Lattice Boltzmann Method .FLUIDS.2020,6 (6)

18. Shen, Jie. Influence of particle-fluid density ratio on the dynamics of finite-size particles in homogeneous isotropic turbulent flows .PHYSICAL REVIEW E.2021 (2):1

19. Yang, Bo. A direct numerical simulation study of flow modulation and turbulent sedimentation in particle-laden downward channel flows .PHYSICS OF FLUIDS.2021,33 (9)

20. Estimation of the dissipation rate of turbulent kinetic energy: a review .Chemical Engineering Science.2020,229 :116133

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