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An LBM study of multichannel flow boiling for electronic thermal management coupling flow instability mitigation Journal article
Chen, Jingtan, Shi, Dan, Khan, Shahid Ali, Dong, Kejian, Mousa, Abd Allah A., Zhao, Jiyun. An LBM study of multichannel flow boiling for electronic thermal management coupling flow instability mitigation[J]. Applied Thermal Engineering, 2023, 239, 122049.
Authors:  Chen, Jingtan;  Shi, Dan;  Khan, Shahid Ali;  Dong, Kejian;  Mousa, Abd Allah A.; et al.
Favorite | TC[WOS]:8 TC[Scopus]:8  IF:6.1/5.8 | Submit date:2024/02/22
Flow Instability  Heat Transfer Enhancement  Lattice Boltzmann Method  Multichannel Flow Boiling  
Dynamic balance of the mesoscale repulsion and attraction with varying surface tension and interaction coefficients on two-phase flow patterns simulated by an improved non-dimensional lattice Boltzmann model Journal article
Su, Yan. Dynamic balance of the mesoscale repulsion and attraction with varying surface tension and interaction coefficients on two-phase flow patterns simulated by an improved non-dimensional lattice Boltzmann model[J]. European Journal of Mechanics, B/Fluids, 2023, 99, 173-186.
Authors:  Su, Yan
Favorite | TC[WOS]:3 TC[Scopus]:3  IF:2.5/2.3 | Submit date:2023/06/05
Attraction  Lattice Boltzmann Model  Mesoscale  Repulsion  Surface Tension  
Mesoscopic scale simulations of heat transport in porous structures Book chapter
出自: Advances in Heat Transfer:Academic Press, 2023, 页码:121-209
Authors:  Yan Su
Favorite | TC[WOS]:2 TC[Scopus]:2 | Submit date:2023/08/03
Mesoscopic Scale  Natural Convection  Nondimensional Lattice Boltzmann Method  Porous Structures  Thermal Diffusion  
Pore scale study on capillary pumping process in three-dimensional heterogeneous porous wicks using Lattice Boltzmann method Journal article
Li, Jian, Zheng, Wenhan, Su, Yan, Hong, Fangjun. Pore scale study on capillary pumping process in three-dimensional heterogeneous porous wicks using Lattice Boltzmann method[J]. International Journal of Thermal Sciences, 2021, 171, 107236.
Authors:  Li, Jian;  Zheng, Wenhan;  Su, Yan;  Hong, Fangjun
Favorite | TC[WOS]:11 TC[Scopus]:13  IF:4.9/4.3 | Submit date:2022/02/21
Capillary Pumping  Lattice Boltzmann Method  Pore Scale  Three-dimensional Random Porous Wick  
A non-uniform stretched mesh scheme for non-dimensional lattice Boltzmann simulations of natural convective flow and heat transfer Journal article
Su, Y., Davidson, J.H.. A non-uniform stretched mesh scheme for non-dimensional lattice Boltzmann simulations of natural convective flow and heat transfer[J]. International Communications in Heat and Mass Transfer, 2021, 105137-105137.
Authors:  Su, Y.;  Davidson, J.H.
Favorite |  | Submit date:2023/08/16
Natural convection  Non-dimensional lattice Boltzmann method  Stretch ratio  
A non-uniform stretched mesh scheme for non-dimensional lattice Boltzmann simulations of natural convective flow and heat transfer Journal article
Su,Yan, Davidson,Jane H.. A non-uniform stretched mesh scheme for non-dimensional lattice Boltzmann simulations of natural convective flow and heat transfer[J]. INTERNATIONAL COMMUNICATIONS IN HEAT AND MASS TRANSFER, 2021, 122, 105137.
Authors:  Su,Yan;  Davidson,Jane H.
Favorite | TC[WOS]:5 TC[Scopus]:5  IF:6.4/5.9 | Submit date:2021/03/11
Boltzmann Method  Natural Convection  Non-dimensional Lattice  Stretch Ratio  
Sparse scattered high performance computing data driven artificial neural networks for multi-dimensional optimization of buoyancy driven heat and mass transfer in porous structures Journal article
Su,Yan, Ng,Tiniao, Li,Zhigang, Davidson,Jane H.. Sparse scattered high performance computing data driven artificial neural networks for multi-dimensional optimization of buoyancy driven heat and mass transfer in porous structures[J]. Chemical Engineering Journal, 2020, 397, 125257.
Authors:  Su,Yan;  Ng,Tiniao;  Li,Zhigang;  Davidson,Jane H.
Favorite | TC[WOS]:11 TC[Scopus]:11  IF:13.3/13.2 | Submit date:2021/03/11
Artificial Neural Network  Controllable Structure Generation Scheme  High Performance Computing  Objective Function  Parallel Non-dimensional Lattice Boltzmann Method  
Sparse scattered high performance computing data driven artificial neural networks for multi-dimensional optimization of buoyancy driven heat and mass transfer in porous structures Journal article
Su, Y., Ng, T.I., Li, Z.G., Davidson, J.H.. Sparse scattered high performance computing data driven artificial neural networks for multi-dimensional optimization of buoyancy driven heat and mass transfer in porous structures[J]. Chemical Engineering Journal, 2020, 125257-125257.
Authors:  Su, Y.;  Ng, T.I.;  Li, Z.G.;  Davidson, J.H.
Favorite |   IF:13.3/13.2 | Submit date:2023/08/16
Artificial neural network  Controllable structure generation scheme  High performance computing  Objective function  Parallel non-dimensional lattice Boltzmann method  
A Lattice Boltzmann Simulation for Thermal Energy Diffusion through a Micro/Nanoscale Thin Film Conference paper
Su, Y.. A Lattice Boltzmann Simulation for Thermal Energy Diffusion through a Micro/Nanoscale Thin Film[C], 2019.
Authors:  Su, Y.
Favorite |  | Submit date:2023/08/16
thermal conductivity  thin film  lattice Boltzmann equation  
Non-dimensional lattice Boltzmann simulations on pore scale double diffusive natural convection in an enclosure filled with random porous media Journal article
Ng T., Su Y.. Non-dimensional lattice Boltzmann simulations on pore scale double diffusive natural convection in an enclosure filled with random porous media[J]. International Journal of Heat and Mass Transfer, 2019, 134, 521-538.
Authors:  Ng T.;  Su Y.
Favorite | TC[WOS]:13 TC[Scopus]:15 | Submit date:2019/02/14
Natural Convection  Non-dimensional Lattice Boltzmann Method  Porosity  Random Porous Media  Volume Fraction