Yangyu Guo

Yangyu Guo Full Professor Harbin Institute of Technology Email: yangyguo/at/126.com

 

Education

☺ Ph. D study (2013-2018)

    Department of Engineering Mechanics, School of Aerospace, Tsinghua University

    Supervisor: Prof. Moran Wang

☺ Bachelor of Science (2009-2013)

       School of Energy Science and Engineering, Harbin Institute of Technology

       Thesis: Design of a 130t/h circulating fluidized bed for bituminite I

       Supervisor: Prof. Rushan Bie

 

Experiences

☺ Visiting student, University of Texas, Austin, 2017-2018

☺ Visiting student, Universitat Autònoma de Barcelona, Spain, September 2014

 

 

Research Interests

☺ Non-equilibrium thermodynamics of micro/nano-scale transport phenomena

☺ Principles of heat transfer under extreme conditions

☺ Thermodynamic optimization theories and applications

 

Honors and Awards

☺ 2017   Tsinghua Friendship Fellowship for Graduate Students

☺ 2016   National Prize for Graduate Students

☺ 2015   National Prize for Graduate Students

☺ 2013   Outstanding Graduate in Heilongjiang Province

☺ 2012   Meritorious Winner in American Mathematical Contest in Modeling (MCM)

 

Publications

In Journal

²  Y.Y. Guo and M. Wang*. Thermodynamics of micro- and nano-scale flow and heat transfer: a mini-review. Journal of Non-Equilibrium Thermodynamics (invited), 49: 221-235, 2024

²  Y. Guo, M. Wang *. Lattice Boltzmann scheme for phonon hydrodynamic transport. International Journal of Thermal Science 171: 107178, 2022

²  Y. Guo*, Z. Zhang, M. Bescond, S.Y. Xiong, M. Wang, M. Nomura*, S. Volz*. Size effect on phonon hydrodynamics in graphite micro- and nanostructures. Physical Review B 104: 075450, 2021

²  Y. Guo, Z. Zhang, M. Nomura, S. Volz, M. Wang*. Phonon vortex dynamics in graphene ribbon by solving Boltzmann transport equation with ab initio scattering rates. International Journal of Heat and Mass Transfer 169: 120981, 2021

²  X.P. Luo, Y.Y. Guo, M. Wang, H. L. Yi*. Direct simulation of second sound in graphene by solving the phonon Boltzmann equation via a multiscale scheme. Physical Review B. 100: 155401, 2019

²  W.L. Miao, Y.Y. Guo, X. Ran, M. Wang*. Deviational Monte Carlo scheme for thermal and electrical transport in metal nanostructures. Physical Review B 99: 205433, 2019

²  Y. Guo^#, X. He^#, W. Huang and M. Wang*. Microstructure Effects on Effective Gas Diffusion Coefficient of Nanoporous Materials. Transport in Porous Media 126: 431-453, 2019

²  X. Ran, YY. Guo, Z.Y. Hu and M. Wang*. Interfacial phonon transport through Si/Ge multilayer film using Monte Carlo scheme with spectral transmissivity. Frontiers in Energy Research 6: 28, 2018

²  Y. Guo, D. Jou, M. Wang*. Nonequilibrium thermodynamics of phonon hydrodynamic model for nanoscale heat transport. Physical Review B 98: 104304, 2018

²  Y. Guo, M. Wang *. Generalized phonon hydrodynamics for nanoscale heat transport at ordinary temperature. Physical Review B 97: 035421, 2018

²  X. Ran, Y. Guo, M. Wang*. Interfacial Phonon Transport with Frequency-dependent Transmissivity by Monte Carlo Simulation. International Journal of Heat and Mass Transfer 123: 616-628, 2018

²  Y. Guo, M. Wang*. Heat transport in two-dimensional materials by directly solving phonon Boltzmann equation under Callaway’s dual relaxation model. Physical Review B 96: 134312, 2017 (IF: 3.836)

²  Y. Guo, M. Wang*. Phonon Hydrodynamics: Progress, Applications and Perspectives. Science China (in Chinese [郭洋裕 王沫然. 声子水动力学. 《中国科学》]), 47(7): 070010, 2017

²  Y. Guo, M. Wang*. Thermodynamic extreme principles for non-equilibrium stationary state in heat conduction Journal of Heat Transfer, 139(7): 071303, 2017

²  Y. Guo, D. Jou, M. Wang*. Macroscopic heat transport equations and heat waves in nonequilibrium states. Physica D. 342: 24-31, 2017

²  X. He, Y. Guo, M. Li, N. Pan and M. Wang*. Effective gas diffusion coefficient of fibrous materials by mesoscopic modeling. International Journal of Heat and Mass Transfer 107: 736-746, 2017

²  Y. Guo, M. Wang*. Thermodynamic analysis of gas flow and heat transfer in microchannels. International Journal of Heat and Mass Transfer 103: 773-782, 2016

²  Y. Guo, M. Wang*. Thermodynamic framework for a generalized heat transport equation. Communications in Applied and Industrial Mathematics 7(2): 167-176, 2016

²  Z. Wang, Y. Guo, M. Wang*. Permeability of high-Kn real gas flow in shale and production prediction by pore-scale modeling. Journal of Natural Gas Science and Engineering 28: 328-337, 2016

²  Y. Guo, D. Jou, M. Wang*. Understanding of flux-limited behaviors of heat transport in nonlinear regime. Physics Letter A 380: 452–457, 2016

²  Y. Guo, M. Wang*. Lattice Boltzmann modeling of phonon transport. Journal of Computational Physics 315: 1-15, 2016

²  Y. Guo, M. Wang*. Phonon hydrodynamics and its applications in nanoscale heat transport. Physics Reports. 595: 1-44, 2015

²  H. Zhang*, Y. Guo, et al. Estimation of Loss Coefficient for Conduit Bends with Circular Cross Section by a Second Law Approach, Heat Transfer Research, 2015, 47(3): 203-217.

²  H. Zhang*, Y. Guo, et al. An entropy production method to investigate the accuracy and stability of numerical simulation of one-dimensional heat transfer. Heat transfer research, 2012, 43: 669-693.

In conference

5.  Y. Guo, M. Wang. Primary exploration of the internal correlation between heat conduction and thermal radiation. Annual National Conference of Engineering Thermophysics, 2015, Dalian, China. (In Chinese)

4.  Y. Guo, M. Wang. Extended thermodynamics of generalized laws in nanoscale heat transport, 13^th Joint European Thermodynamics Conference, May 20-22, 2015, Nancy, France.

3.  Y. Guo, M. Wang. Lattice Boltzmann simulation of phonon hydrodynamics. Annual National Conference of Engineering Thermophysics, 2014, Xi’an, China. (In Chinese)

2.  Y. Guo, H. Yu, H. Zhang, et al. Thermodynamic analysis of bionic microstructure turbulence drag reduction mechanism. Annual National Conference of Engineering Thermophysics, 2013, Chongqing, China. (In Chinese)

1.  Y. Guo, H. Zhang, et al. Entropy production characteristics through n-heptane evaporation in low Reynolds number incoming air flow. Annual National Conference of Engineering Thermophysics, 2012, Dongguan, China. (In Chinese)

Book & Chapter

1.  H. Zhang, Y.Y. Guo, H.P. Tan and Y. Li. A Concept of Discretization Error Indicator for Simulating Thermal Radiation by Finite Volume Method Based on an Entropy Generation Approach. Finite Volume Method. Ed. by Radostina Petrova, INTECH, 2012.