郭江峰 教授

郭江峰，博士，教授

通讯地址：北京市朝阳区北三环东路15号北京化工大学科技大厦307房间

联系方式：gjf@buct.edu.cn;gjf1200@126.com

个人主页：https://www.researchgate.net/profile/Jiangfeng-Guo (ResearchGate)

https://faculty.buct.edu.cn/mech/gjf2/main.htm(教师主页)

个人概况：

郭江峰，男，山东菏泽市人，中共党员，现任北京化工大学教授、博士生导师。曾任英国帝国理工学院研究员、中国科学院大学岗位教授、中国科学院工程热物理研究所项目研究员等。2006年毕业于华北电力大学获工学和工商管理双学士学位，2011年毕业于山东大学获工学博士学位。

主要研究方向包括：传热强化理论与节能技术、超临界二氧化碳能源利用技术、高效紧凑式换热器开发、新型储能系统构建与优化、氢能换热技术、高效热管理技术、太阳能分光谱利用等。

作为负责人主持国家重点研发计划课题、欧盟地平线2020科技人才项目、国家自然科学基金项目、国家两机重大专项课题、中国科学院稳定支持基础研究领域青年团队计划子任务、中国科学院国际创新基金项目、中国科学院人才计划项目、地方政府及企业合作项目等十余项项目(课题)，作为主要技术骨干参与国家973计划、国家重点研发计划、中科院先导专项等多项重要项目。

发表学术论文100余篇，其中以第1/通讯作者发表SCI期刊论文80余篇，JCR排名Q1区期刊论文占比80%以上，总被引频次3300余次(Scopus)。连续多年入选美国斯坦福大学发布的“世界前2%顶级科学家”(world’sTop2% scientists)年度和终身科学影响力双榜单。参与编写三部英文学术著作(分别由德国Springer和美国IGIGlobal出版)。申请/授权国家发明专利20多项。

曾获全国百篇优秀博士学位论文提名、中国科学院卢嘉锡青年人才奖、欧盟玛丽居里学者、中国100篇最具影响优秀国内学术论文等。担任多个国际重要学术会议(HEFAT-ATE2022、ICSPC2024等)执行或技术委员会等。被邀请担任国际SCI期刊《Frontiersin Energy Research》副主编、《Frontiersin Heat and Mass Transfer》期刊编委和《CarbonNeutrality》、《CleanEnergy Science andTechnology》期刊青年编委等。中国水力发电工程学会压缩空气储能专业委员会第一届委员会委员、中国化工学会会员、北京能源与环境学会专家委员会专家等；教育部研究生教育评估平台评议专家、国家自然科学基金项目、国家重点研发计划项目等多个重要项目评审专家等。已指导多名博士和硕士研究生，多人次获得国家奖学金、中国工程热物理学会青年优秀论文奖等。

教育背景：

2006.09-2011.06山东大学，热能工程专业，博士学位

2002.09-2006.07热能与动力工程、工商管理专业，双学士学位

工作履历：

2024.06-至今北京化工大学，教授

2021.05-2023.06英国帝国理工学院，研究员

2011.07-2024.06中国科学院工程热物理研究所，助理研究员、副研究员、项目研究员

教学工作：

主讲《工程热力学》国际英文课程

参与讲授国家一流课程《过程设备设计》国际英文、国内中文课程

论文与专利：

部分论文(“*”代表通讯作者)

1. J.Guo*, G. Huang, C.N.Markides, Solar harvesting maximisation in spectral-splittingphotovoltaic-thermal systems via integrated radiative cooling,Energy (2025) 136455. (JCR分区:Q1)

2. Y.Zhao, Y. Xie, J. Song, J.Guo, W. Li, Z. Deng,Heat transfer mechanism of topologically-optimised fin structures inlatent heat storage units, International Journal of Heat and MassTransfer 239 (2025) 126438. (JCR分区:Q1)

3. J.Guo*, Z. Wu, F.Zhang, H. Yu, C. Qian, Theoretical studies on a dual-function systemintegrating solar heating and radiative cooling for year-roundenergy saving, Solar Energy 288 (2025) 113293.

4. J.Chen, W. Du, K. Cheng, X. Li, J.Guo, P. Lv, H. Dong,Design analysis of a hybrid printed circuit heat exchanger forprecooling in hydrogen refueling station, InternationalCommunications in Heat and Mass Transfer 163 (2025) 108765.

5. J.Guo*, H. Yu, Flow andHeat Transfer Features of Supercritical Pressure CO₂in Horizontal Flows under Whole-Wall Heating Conditions, Frontiersin Heat and Mass Transfer 22 (2024) 1575--1595.

6. J.Chen, K. Cheng, X. Li, J.Guo, X. Huai,Thermodynamic analysis and equilibration response time prediction ofrecuperator in the SCO₂Brayton cycle, Energy 308 (2024) 132807. (JCR分区:Q1)

7. J.Guo*,X. Huai, Maximizing Electric Power through Spectral-SplittingPhotovoltaic-Thermoelectric Hybrid System Integrated with RadiativeCooling, Advanced Science (2023) 2206575. (JCR分区:Q1)

8. Z.Han, J.Guo*,X. Huai, Theoretical analysis of a novel PCHE with enhanced ribstructures for high-power supercritical CO₂Brayton cycle system based on solar energy, Energy 270 (2023)126928. (JCR分区:Q1)

9. J.Guo*,J. Song, S. Narayan, K.S. Pervunin, C.N. Markides, Numericalinvestigation of the thermal-hydraulic performance of horizontalsupercritical CO₂flows with half-wall heat-flux conditions, Energy 264 (2023) 125845.(JCR分区:Q1)

10. J.Guo*, Maximizinguninterrupted solar electricity in spectral-splittingphotovoltaic-thermal systems integrated with CO₂battery, Journal of Energy Storage 66 (2023) 107402. (影响因子:8.907; JCR分区:Q1)

11. Z.Han, J. Guo*,J. Chen, X. Huai, Experimental and numerical investigations onthermal-hydraulic characteristics of supercritical CO2 flows inprinted circuit heat exchangers, International Journal of ThermalSciences 194 (2023) 108573.

12. Z.Han, X. Cui, J. Guo*,H. Zhang, J. Zhou, K. Cheng, H. Zhang X. Huai, Experimental andnumerical studies on the thermal-hydraulic performance of a novelairfoil fins printed circuit heat exchanger, International Journalof Heat and Mass Transfer 217 (2023) 124655. (JCR分区:Q1)

13. X.Liu, J.Guo*,Z. Han, K. Cheng, X. Huai, Studies on thermal-hydrauliccharacteristics of supercritical CO₂flows with non-uniform heat flux in a tubular solar receiver,Renewable Energy 201 (2022) 291-304. (JCR分区:Q1)

14. Z.Han, J.Guo*,H. Liao, Z. Zhang, X. Huai, Numerical investigation on thethermal-hydraulic performance of supercritical CO₂in a modified airfoil fins heat exchanger, The Journal ofSupercritical Fluids 187 (2022) 105643. (JCR分区:Q2)

15. J.Guo*,J. Song, Y. Zhao, K.S. Pervunin, C.N. Markides, Thermo-hydraulicperformance of heated vertical flows of supercritical CO₂,International Journal of Heat and Mass Transfer 199 (2022) 123437.(JCR分区:Q1)

16. J.Guo*,J. Song, Z. Han, K.S. Pervunin, C.N. Markides, Investigation of thethermohydraulic characteristics of vertical supercritical CO₂flows at cooling conditions, Energy 256 (2022) 124628. (JCR分区:Q1)

17. J.Chen, J.Guo*,X. Li, X. Huai, K. Cheng, Thermal-hydraulic performance ofmist/compressed humid air two-phase flow in an airfoil channelrecuperator, Applied Thermal Engineering 201 (2022) 117802. (JCR分区:Q1)

18. H.Zhang, J.Guo*,X. Cui, J. Zhou, X. Huai, H. Zhang, K. Cheng, Z. Han, Experimentaland numerical investigations of thermal-hydraulic characteristics ina novel airfoil fin heat exchanger, International Journal of Heatand Mass Transfer 175 (2021) 121333. (JCR分区:Q1)

19. H.Zhang, K. Cheng, X. Huai*, J. Zhou, J.Guo,Experimental and Numerical Study of an 80-kW Zigzag Printed CircuitHeat Exchanger for Supercritical CO₂Brayton Cycle, Journal of Thermal Science 30(4) (2021) 1289-1301.

20. Z.Han, J.Guo*,H. Zhang, J. Chen, X. Huai, X. Cui, Experimental and numericalstudies on novel airfoil fins heat exchanger in flue gas heatrecovery system, Applied Thermal Engineering 192 (2021) 116939.(JCR分区:Q1)

21. Z.Han, J.Guo*,X. Huai, Optimization method of a novel airfoil fin heat exchangerbased on the entransy dissipation theory, SCIENTIA SINICATechnologica 51(10) (2021) 1219-1230.

22. K.Cheng, J. Zhou, X. Huai, J.Guo,Experimental exergy analysis of a printed circuit heat exchanger forsupercritical carbon dioxide Brayton cycles, Applied ThermalEngineering 192 (2021) 116882. (JCR分区:Q1)

23. J.Chen, J.Guo*,X. Li, X. Huai, K. Cheng, H. Zhang, Z. Han, Thermal-hydraulicperformance of compressed humid air flowing in a recuperator,Applied Thermal Engineering 188 (2021) 116620. (JCR分区:Q1)

24. J.Zhou, K. Cheng, H. Zhang, B. Liu, X. Huai*, J.Guo,H. Zhang, X. Cui, Test platform and experimental test on 100 kWclass Printed Circuit Heat Exchanger for Supercritical CO₂Brayton Cycle, International Journal of Heat and Mass Transfer 148(2020) 118540. (JCR分区:Q1)

25. H.Zhang, J.Guo*,X. Cui, X. Huai, Performance analysis of supercritical pressure CO₂in several enhanced tubes with non-uniform heat flux, AppliedThermal Engineering 180 (2020) 115823. (JCR分区:Q1)

26. H.Zhang, J.Guo*,X. Cui, X. Huai, Heat transfer performance of supercritical pressureCO₂in a non-uniformly heated horizontal tube, International Journal ofHeat and Mass Transfer 155 (2020) 119748. (JCR分区:Q1)

27. M.Xu, Z.L. Liu, X.L. Huai, L.T. Lou, J.F.Guo,Screening of metal-organic frameworks for water adsorption heattransformation using structure-property relationships, RSC Advances10(57) (2020) 34621-34631. (JCR分区:Q2)

28. K.Cheng, J. Zhou, H. Zhang, X. Huai, J.Guo,Experimental investigation of thermal-hydraulic characteristics of aprinted circuit heat exchanger used as a pre-cooler for thesupercritical CO₂Brayton cycle, Applied Thermal Engineering 171 (2020) 115116.(JCR分区:Q1)

29. H.Zhang, J.Guo*,X. Huai, X. Cui, K. Cheng, Buoyancy effects on coupled heat transferof supercritical pressure CO₂in horizontal semicircular channels, International Journal of Heatand Mass Transfer 134 (2019) 437-449. (JCR分区:Q1)

30. H.Zhang, J.Guo*,X. Huai, X. Cui, Thermodynamic performance analysis of supercriticalpressure CO₂in tubes, International Journal of Thermal Sciences 146 (2019)106102. (JCR分区:Q1)

31. H.Zhang, J.Guo*,X. Huai, K. Cheng, X. Cui, Studies on the thermal-hydraulicperformance of zigzag channel with supercritical pressure CO₂,The Journal of Supercritical Fluids 148 (2019) 104-115. (JCR分区:Q2)

32. J.Guo*,M. Xiang, H. Zhang, X. Huai, K. Cheng, X. Cui, Thermal-hydrauliccharacteristics of supercritical pressure CO₂in vertical tubes under cooling and heating conditions, Energy 170(2019) 1067-1081. (JCR分区:Q1)

33. J.Guo*,X. Cui, H. Zhang, X. Huai, K. Cheng, Performance analysis of heatexchanger for fluids with variable properties, Energy Procedia 158(2019) 5724-5734.

34. J.Guo*,X. Cui, X. Huai, K. Cheng, H. Zhang, The coordination distributionanalysis on the series schemes of heat exchanger system,International Journal of Heat and Mass Transfer 129 (2019) 37-46.(JCR分区:Q1)

35. X.Cui, H. Zhang, J.Guo*,X. Huai, M. Xu, Analysis of two-stage waste heat recovery based onnatural gas-fired boiler, International Journal of Energy Research43 (2019) 8898– 8912.(JCR分区:Q1)

36. X.Cui, M. Xiang, J.Guo*,X. Huai, H. Zhang, K. Cheng, Analysis of coupled heat transfer ofsupercritical CO₂from the viewpoint of distribution coordination, The Journal ofSupercritical Fluids 152 (2019) 104560. (JCR分区:Q2)

37. X.Cui, J.Guo*,X. Huai, H. Zhang, K. Cheng, J. Zhou, Numerical investigations onserpentine channel for supercritical CO₂recuperator, Energy 172 (2019) 517-530. (JCR分区:Q1)

38. J.Guo*,X. Huai, K. Cheng, X. Cui, H. Zhang, The effects of nonuniform inletfluid conditions on crossflow heat exchanger, International Journalof Heat and Mass Transfer 120 (2018) 807-817. (JCR分区:Q1)

39. J.Guo*,X. Huai, K. Cheng, The comparative analysis on thermal storagesystems for solar power with direct steam generation, RenewableEnergy 115 (2018) 217-225. (JCR分区:Q1)

40. X.Cui, J.Guo*,X. Huai, K. Cheng, H. Zhang, M. Xiang, Numerical study on novelairfoil fins for printed circuit heat exchanger using supercriticalCO₂,International Journal of Heat and Mass Transfer 121 (2018) 354-366.(JCR分区:Q1)

41. M.Xu, J. Cai, J.Guo,X. Huai, Z. Liu, H. Zhang, Technical and economic feasibility of theIsopropanol-Acetone-Hydrogen chemical heat pump based on a lab-scaleprototype, Energy 139 (2017) 1030-1039. (JCR分区:Q1)

42. M.Xiang, J.Guo*,X. Huai, X. Cui, Thermal analysis of supercritical pressure CO₂in horizontal tubes under cooling condition, The Journal ofSupercritical Fluids 130 (2017) 389-398. (JCR分区:Q2)

43. J.Guo*,X. Huai, Coordination analysis of cross-flow heat exchanger underhigh variations in thermodynamic properties, International Journalof Heat and Mass Transfer 113 (2017) 935-942. (JCR分区:Q1)

44. J.Guo*,X. Huai, Performance Analysis of Printed Circuit Heat Exchanger forSupercritical Carbon Dioxide, ASME Journal of Heat Transfer 139(6)(2017) 061801.

45. J.Guo*,X. Huai, Z. Liu, Performance investigation of parabolic trough solarreceiver, Applied Thermal Engineering 95 (2016) 357-364. (JCR分区:Q1)

46. J.Guo*,X. Huai, The heat transfer mechanism study of three-tank latent heatstorage system based on entransy theory, International Journal ofHeat and Mass Transfer 97 (2016) 191-200. (JCR分区:Q1)

47. J.Guo*,X. Huai, Numerical investigation of helically coiled tube from theviewpoint of field synergy principle, Applied Thermal Engineering 98(2016) 137-143. (JCR分区:Q1)

48. J.Guo*,X. Huai, Multi-parameter optimization design of parabolic troughsolar receiver, Applied Thermal Engineering 98 (2016) 73-79. (JCR分区:Q1)

49. J.Guo*,Design analysis of supercritical carbon dioxide recuperator, AppliedEnergy 164 (2016) 21-27. (影响因子:11.45; JCR分区:Q1)

50. J.Guo,X. Huai, M. Xu, Thermodynamic analysis of anisopropanol–acetone–hydrogen chemical heat pump,International Journal of Energy Research 39(1) (2015) 140-146.(JCR分区:Q1)

51. J.Guo,X. Huai*, M. Xu, Study on Isopropanol–Acetone–Hydrogenchemical heat pump of storage type, Solar Energy 110(0) (2014)684-690. (JCR分区:Q2)

52. M.Xu, F. Xin, X. Li, X. Huai*, J.Guo,H. Liu, Equilibrium Model and Performances of anIsopropanol–Acetone–Hydrogen Chemical Heat Pump with aReactive Distillation Column, Industrial & Engineering ChemistryResearch 52(11) (2013) 4040-4048. (JCR分区:Q2)

53. X.Li, J. Cai, F. Xin, X. Huai, J.Guo,Lattice Boltzmann simulation of endothermal catalytic reaction incatalyst porous media, Applied Thermal Engineering 50(1) (2013)1194-1200. (JCR分区:Q1)

54. J.Guo,X. Huai*, X. Li, J. Cai, Y. Wang, Multi-objective optimization ofheat exchanger based on entransy dissipation theory in anirreversible Brayton cycle system, Energy 63 (2013) 95-102. (JCR分区:Q1)

55. J.Guo,X. Huai*, Thermodynamic analysis of lead–bismuth eutecticturbulent flow in a straight tube, Energy 57 (2013)600-606. (JCR分区:Q1)

56. J.Guo,X. Huai*, Optimization design of heat exchanger in an irreversibleregenerative Brayton cycle system, Applied Thermal Engineering 58(1–2) (2013) 77-84. (JCR分区:Q1)

57. J.Guo*,J. Cai, H.G. Wang, Performance analysis of an irreversibleregenerative intercooled Brayton cycle, International Journal ofExergy 11(3) (2012) 271-285.

58. J.Guo,M. Xu, Y. Tao, X. Huai, The effect of temperature-dependentviscosity on entropy generation in curved square microchannel,Chemical Engineering and Processing: Process Intensification 52(0)(2012) 85-91. (JCR分区:Q2)

59. J.Guo,M. Xu, The application of entransy dissipation theory inoptimization design of heat exchanger, Applied Thermal Engineering36 (2012) 227-235. (JCR分区:Q1)

60. J.Guo,X. Huai, X. Li, M. Xu, Performance analysis ofIsopropanol–Acetone–Hydrogen chemical heat pump, AppliedEnergy 93 (2012) 261-267. (影响因子:11.45; JCR分区:Q1)

61. J.Guo,X. Huai, Optimization design of recuperator in a chemical heat pumpsystem based on entransy dissipation theory, Energy 41(1) (2012)335-343. (JCR分区:Q1)

62. M.Xu, J.Guo,L. Wang, L. Cheng, Thermal wave interference as the origin of theovershooting phenomenon in dual-phase-lagging heat conduction,International Journal of Thermal Sciences 50(5) (2011) 825-830.(JCR分区:Q1)

63. X.Li, J.Guo,M. Xu, L. Cheng, Entransy dissipation minimization for optimizationof heat exchanger design, Chinese Science Bulletin 56(20) (2011)2174-2178.

64. J.Guo,M. Xu, L. Cheng, Effect of temperature-dependent viscosity on theentransy of both fluids in heat exchangers, Chinese Science Bulletin56(23) (2011) 1934-1939.

65. J.Guo,M. Xu, L. Cheng, The entransy dissipation minimization principleunder given heat duty and heat transfer area conditions, ChineseScience Bulletin 56(19) (2011) 2071-2076.

66. J.Guo*,M. Xu, L. Cheng, Numerical investigations of curved square channelfrom the viewpoint of field synergy principle, International Journalof Heat and Mass Transfer 54 (2011) 4148-4151. (JCR分区:Q1)

67. J.Guo*,M. Xu, L. Cheng, The influence of viscous heating on the entransy intwo-fluid heat exchangers SCIENCE CHINA Technological Sciences 54(5)(2011) 1267-1274. (JCR分区:Q2)

68. J.Guo,M. Xu*, L. Cheng, Second law analysis of curved rectangularchannels, International Journal of Thermal Sciences 50(5) (2011)760-768. (JCR分区:Q1)

69. J.Guo,M. Xu, J. Cai, X. Huai, Viscous dissipation effect on entropygeneration in curved square microchannels, Energy 36(8) (2011)5416-5423. (JCR分区:Q1)

70. J.Guo,M. Xu*, L. Cheng, Numerical investigations of circular tube fittedwith helical screw-tape inserts from the viewpoint of field synergyprinciple, Chemical Engineering and Processing: ProcessIntensification 49(4) (2010) 410-417. (JCR分区:Q2)

71. J.Guo,M. Xu*, L. Cheng, Thermodynamic analysis of waste heat powergeneration system, Energy 35(7) (2010) 2824-2835. (JCR分区:Q1)

72. J.Guo,M. Xu, L. Cheng, Principle of equipartition of entransy dissipationfor heat exchanger design, SCIENCE CHINA Technological Sciences53(5) (2010) 1309-1314. (JCR分区:Q2)

73. J.Guo,L. Cheng, M. Xu, Mutli-objective optimization of heat exchangerdesign by entropy generation minimization, ASME Journal of HeatTransfer 132(8) (2010) 081801.

74. J.Guo,L. Cheng, M. Xu, The entropy generation minimization based on therevised entropy generation number, International Journal of Exergy7(5) (2010) 607-625.

75. M.Xu, J.Guo,L. Cheng, Application of entransy dissipation theory in heatconvection, Frontiers of Energy and Power Engineering in China 3(4)(2009) 402-405.

76. J.Guo,M. Xu*, L. Cheng, The application of field synergy number inshell-and-tube heat exchanger optimization design, Applied Energy86(10) (2009) 2079-2087. (影响因子:11.45; JCR分区:Q1)

77. J.Guo,L. Cheng, M. Xu, Entransy dissipation number and its application toheat exchanger performance evaluation, Chinese Science Bulletin54(15) (2009) 2708-2713.

78. J.Guo,L. Cheng, M. Xu, Optimization design of shell-and-tube heatexchanger by entropy generation minimization and genetic algorithm,Applied Thermal Engineering 29(14-15) (2009) 2954-2960. (JCR分区:Q1)

79. J.Guo*,J. Song, K.S. Pervunin, C.N. Markides, Heat exchanger arrangementsin supercritical CO₂Brayton cycle systems: an analysis based on the distributioncoordination principle, 16th international conference on heattransfer, fluid mechanics and thermodynamics, Amsterdam, Holland,2022.

80. J.Guo*,H. Zhang, X. Cui, X. Huai, The heat transfer analysis of lowtemperature recuperator in supercritical CO₂Brayton cycle, Applied Energy Symposium: MIT A+B, Boston, USA, 2019.

81. H.Zhang, K. Cheng, X. Huai*, J.Guo,Performance analysis of printed circuit heat exchanger forsupercritical carbon dioxide and water, IOP Conference Series:Materials Science and Engineering 721(1) (2020) 012039.

82. H.Zhang, J.Guo*,M. Xiang, X. Huai, K. Cheng, X. Cui, Numerical studies on thecoupled heat transfer characteristics of supercritical pressure CO₂under cooling condition, The 16th International Heat TransferConference, Beijing, China, August 2018.

83. J.Guo*,X. Huai, K. Cheng, X. Cui, H. Zhang, Thermal analysis of heatexchanger with supercritical pressure CO₂,16th International Heat Transfer Conference, Beijing, China, August2018.

84. J.Guo*,X. Cui, H. Zhang, X. Huai, K. Cheng, Performance analysis of heatexchanger for fluids with variable properties, The 10thInternational Conference on Applied Energy – ICAE2018, HongKong, China, August 2018.

85. X.Cui,J. Guo*,X. Huai, K. Cheng, H. Zhang, M. Xiang, Numerical investigation onconvective heat transfer of supercritical pressure CO₂in serpentine channel, the 16th International Heat TransferConference, Beijing, China, August 2018.

86. J. Guo*,X. Huai, Heat transfer enhancement mechanism and optimisation methodfor supercritical CO₂heat exchanger, The 1st International Conference on SupercriticalCO₂Power System, Beijing, China, June 29 – July 1 2018.

87. C.Qiao*, Z. Zhang, J.Guo,J. Zhang, Development and Application of Collaborative OptimizationSoftware for Plate-fin Heat Exchanger, The 1st International Globalon Renewable Energy and Development, IOP Publishing Ltd, Bristol,2017.

88. J.Guo,X. Huai*, Entransy dissipation in a straight tube with leadbismuthturbulent flow, 26th International Conference on Efficiency, Cost,Optimization, Simulation and Environmental Impact of Energy Systems,ECOS 2013, July 16, 2013 - July 19, 2013, China InternationalConference Center for Science and Technology, Guilin, China, 2013.

89. Guo,J.*, Xu, M., Cheng,L. (2010): A new criterion for assessing heat exchanger performance.Proceedings of the 14^thInternational Heat Transfer Conference at Washington, USA, August2010.

90. 黄俊杰，韩增孝，郭江峰*，淮秀兰，超临界CO₂微通道换热器研究进展，制冷学报44(04)(2023)1-14.

91. 刘晓凯,郭江峰*,韩增孝,张海燕,淮秀兰,超临界压力CO₂在非均匀加热竖直管内的换热特性研究,工程热物理学报43(07)(2022) 1951-1957.

92. 韩增孝,郭江峰*,张海燕,陈俊霖,淮秀兰,湿化循环燃机回热器加压湿空气流动换热特性研究,工程热物理学报42(11)(2021) 2899-2910.

93. 韩增孝,郭江峰*,淮秀兰,基于火积耗散理论的新翼型换热器优化方法研究,中国科学：技术科学51(10) (2021) 1219-1230.

94. 郭江峰*,张海燕,崔欣莹,淮秀兰,韩增孝,低品位烟气余热回收换热器热力学分析,工程热物理学报41(1)(2020) 39-45.

95. 张海燕,郭江峰*,淮秀兰,PCHE内轴向导热对局部换热性能的影响研究,化工学报70(2019) 4590-4598.

96. 曹勇,郭江峰,党睿,张思思,柳松,崔治国,公共机构高效用能关键技术的研究,中国基础科学·科技计划21(5)(2019) 31-40.

97. 相梦如,郭江峰*,淮秀兰,成克用,崔欣莹,超临界压力CO2水平管内冷却换热机理研究,工程热物理学报38(9)(2017) 1929-1934.

98. 郭江峰,许明田&,程林,基于火积耗散数最小的板翅式换热器优化设计,工程热物理学报32(05)(2011) 827-831.

99. 郭江峰*,许明田,程林,两流体换热器内粘性热对两流体火积的影响,中国科学:技术科学41(05)(2011) 621-627.

100. 郭江峰,许明田*,程林,换热器内随温度变化的黏度对两流体火积的影响,科学通报56(23)(2011) 1934-1939.

101. 郭江峰,许明田*,程林,换热器设计中的火积耗散均匀性原则,中国科学：技术科学40(06)(2010) 671-676.

102. 郭江峰,许明田*,程林,换热量和换热面积给定时的火积耗散最小原则,科学通报(2010)3141-3146.

103. 郭江峰,程林,许明田*,火积耗散数及其应用,科学通报54(19)(2009) 2998-3002.

部分专利

1. 一种集成太阳能聚光分光光伏-热的压缩二氧化碳储能系统，CN202410931429.6

2. 一种带有梯级蓄热的补热型二氧化碳混合工质储能系统，CN202410931474.1

3. 一种集成蓄冷蓄热的太阳能加热和辐射冷却建筑节能系统及控制方法，202510749305.0

4. 强化换热的方法.CN: CN110779378B

5. 一种印刷电路板换热器入口分流处结构.CN: CN108180779A

6. 带有流线形肋结构的换热板及包含其的印刷电路板换热器.CN: CN107687780A

7. 用于印刷电路板换热器的换热板.CN: CN107024134A

8. 一种换热板和气体 液体换热器.CN: CN106931821A

9. 一种用于太阳能直接蒸发系统的相变蓄热装置.CN: CN105157251A

10. 一种太阳能直接蒸汽发生系统的模拟装置及方法.CN: CN105136506A

11. 基于热化学储能的电蓄热锅炉、供能系统及方法.CN: CN109855306A

12. 一种测量超临界CO₂回热器和冷却器性能的装置和方法.CN: CN107314567A

13. 一种高温液态金属两级冷却设备和方法.CN: CN105825900A

14. 一种正反旋向交替的间断内插式螺旋翅片强化换热管.CN: CN104864760A

15. 一种液态金属与高压气体流动换热装置及方法.CN: CN104599727A

16. 一种高温液态金属流量在线标定装置.CN: CN102721452A

17. 一种应用于液态铅铋合金实验回路的预热器.CN: CN102635933A

18. 一种微通道热沉及微通道热沉性能测试装置.CN: CN102620590A

奖励与荣誉：

1. 连续多年入选“全球前2%顶尖科学家”(world’sTop2% Scientists)年度和终身影响力双榜单，2021~2025

2. 欧盟玛丽居里学者，欧盟委员会，2021

3. 中国科学院卢嘉锡青年人才奖，中国科学院，2015

4. 全国百篇优秀博士学位论文提名，国务院学位委员会、教育部，2014

5. 北京青年优秀科技论文奖，北京市科协，2016

6. 中国100篇最具影响优秀国内学术论文，中国科技信息研究所，2013

7. 国际埃尼奖（EniAward）提名，EniAward组委会，2017/2016

8. 《中国科学：技术科学》优秀审稿人，期刊编委会，2018

9. 《工程热物理学报》突出贡献者，期刊编委会，2018/2019

10. 中国科学院青年创新促进会人才计划，中国科学院，2014

11. 中科院工程热物理所攀登人才计划，中科院工程热物理所，2019

12. 领跑者5000-中国精品科技期刊顶尖学术论文，中国科技信息研究所，2012

13. 山东大学优秀博士学位论文,山东大学，2012

14. 山东省研究生优秀科技创新成果奖，山东省科技厅、教育厅，2011