基本信息
姓名:王存海
系所:热科学与能源工程系
职称:副教授
邮箱:wangcunhai@ustb.edu.cn
教育及工作经历
2020.12----至今 北京科技大学能源与环境工程学院,副教授
2018.07-2020.12 北京科技大学能源与环境工程学院,师资博士后
2015.10-2016.10 美国加州大学伯克利分校,联合培养博士(导师:Costas P. Grigoropoulos 教授)
2013.07-2018.07 哈尔滨工业大学能源学院,博士(导师:易红亮 教授)
2011.07-2013.07 哈尔滨工业大学能源学院,硕士(导师:易红亮 教授)
2007.09-2011.07 哈尔滨工业大学能源学院,学士
2018.07-2020.12 北京科技大学能源与环境工程学院,师资博士后
2015.10-2016.10 美国加州大学伯克利分校,联合培养博士(导师:Costas P. Grigoropoulos 教授)
2013.07-2018.07 哈尔滨工业大学能源学院,博士(导师:易红亮 教授)
2011.07-2013.07 哈尔滨工业大学能源学院,硕士(导师:易红亮 教授)
2007.09-2011.07 哈尔滨工业大学能源学院,学士
研究领域
空天热辐射能量开发与利用
1、微纳结构热辐射特性调控机制(光谱选择性热辐射、定向热辐射机理、高温热辐射特性等)
2、新能源与储能技术中的热管理(辐射制冷、光热/光电/热电转化、海水淡化、智能窗户等)
3、仿生智能薄膜与协同能质调控(智能响应薄膜精准构筑及其在物质分离与光热调控中的应用研究)
4、多光谱兼容隐身结构设计开发
1、微纳结构热辐射特性调控机制(光谱选择性热辐射、定向热辐射机理、高温热辐射特性等)
2、新能源与储能技术中的热管理(辐射制冷、光热/光电/热电转化、海水淡化、智能窗户等)
3、仿生智能薄膜与协同能质调控(智能响应薄膜精准构筑及其在物质分离与光热调控中的应用研究)
4、多光谱兼容隐身结构设计开发
研究生培养
硕士培养:每年招收硕士研究生2~3人.
基本要求:对学术感兴趣,有良好的科研素养(重要);对生活有热情,有健康的作息方式(很重要);对人生有规划,有正派的生活作风(最重要).
欢迎有志于从事太阳能利用、辐射制冷、新能源材料等领域基础和应用研究的同学申报,课题组提供自由开放的科研氛围以及出国交流机会(包括UC Berkeley,Stanford University,UCLA等国际名校),欢迎你的加入!
基本要求:对学术感兴趣,有良好的科研素养(重要);对生活有热情,有健康的作息方式(很重要);对人生有规划,有正派的生活作风(最重要).
欢迎有志于从事太阳能利用、辐射制冷、新能源材料等领域基础和应用研究的同学申报,课题组提供自由开放的科研氛围以及出国交流机会(包括UC Berkeley,Stanford University,UCLA等国际名校),欢迎你的加入!
开设课程
1.太阳能转换原理与技术(本科生专业核心课,48学时)
2.高等传热学(辐射换热部分)(研究生学科专业课,48学时)
2.高等传热学(辐射换热部分)(研究生学科专业课,48学时)
学术/社会兼职
1.建筑热辐射技术研究中心,副秘书长
2.中国工程热物理学会会员、中国制冷学会会员、中国材料研究学会会员
3.The Innovation, Nano-Micro Letters期刊青年编委
4.Science, Nature Sustainability, Joule, Energy & Environmental Science等期刊审稿人.
2.中国工程热物理学会会员、中国制冷学会会员、中国材料研究学会会员
3.The Innovation, Nano-Micro Letters期刊青年编委
4.Science, Nature Sustainability, Joule, Energy & Environmental Science等期刊审稿人.
代表性论文及著作
近五年第一/通讯作者论文
[1]Fan Y, Chen H, Liu X, Zhao Y, Huang Y*, Liu J*, Wang C*. Radiative cooling in outer space: Fundamentals, advances in materials and applications, and perspectives. Advanced Materials, 2505601, 2025. (一区TOP, IF2025: 26.8)
[2]Hou M, Chen H, Li S, Zhang X, Chen J, Jiang Z*, Wang C*, Lai NC*, Ding Y. A tri-mode photothermal, phase-change, and radiative-cooling film for all-day thermoelectric generation. Advanced Materials, 2505601, 2025. (一区TOP, IF2025: 26.8)
[3]Li H, Ma J, Chen H, Hong W*, Lan J, Chang Y, Zhang H, Zhang L, Niu X, Li Y, Liu J*, Wang C*. Interfacial photothermal membrane distillation for direct solar water production. Advanced Functional Materials, e15845, 2025. (一区TOP, IF2025: 19.0)
[4]Chen H, Liu X, Liu J*, Wang F*, Wang C*. Radiative cooling applications for enhanced energy efficiency: System designs, achievements, and outlook. The Innovation, 6: 100999, 2025. (一区TOP, IF2025: 25.7)
[5]Wang C*, Wang W, Chen H, Liu J*, Mimicking scarab beetle elytra in colorful radiative coolers. Matter, 8: 101951, 2025. (一区TOP, IF2024: 18.4)
[6]Wang C*, Chen T, Chen H, Liu J*, Yi H*. Broadband directive thermal emission supported by local surface plasmon and magnetic polaritons. ACS Photonics, 12(4): 2226–2232, 2025. (一区TOP, IF2025: 6.7)
[7]Zhang K, Xie L, Chen Z, Chen H, Wang C*. A high-performance dynamic thermal regulator based on the phase-switchable In3SbTe2. Energy, 325, 15: 136227, 2025. (一区TOP, IF2025: 9.4)
[8]Cheng Chunyun, Jingchong Liu*, Fuqiang Wang*, Cunhai Wang*. Photonic structures in multispectral camouflage: From static to dynamic technologies. Materials Today, 85: 253–281, 2025. (一区TOP, IF2025: 22.0)
[9]Wei J, Chen H, Liu J*, Wang F*, Wang C*. Radiative cooling technologies toward enhanced energy efficiency of solar cells: Materials, systems, and perspectives. Nano Energy, 136, 110680, 2025. (一区TOP, IF2025: 17.1)
[10]Chen H, Wei J, Liu X, Liu J*, Wang C*. Assessing sky radiative cooling power with considering the cloud effects. Applied Thermal Engineering, 278: 127192, 2025.
[11]Chen H, Wang C*. Bridging radiative cooling materials and applications towards alleviating global energy issues. The Innovation Energy, 2: 100090, 2025.
[12]Wang C*, Bian H, Fan D, Zhang P*, Liu J*. Near-field radiative heat transfer between metaterminals composed of SiC plate-supported LiH nanoparticle arrays. International Journal of Heat and Mass Transfer, 236: 126375, 2025.
[13]Wang C*, Chen H, Wang F*. Passive daytime radiative cooling materials toward real-world applications. Progress in Materials Science, 144: 101276, 2024. (ESI高被引, 一区TOP, IF2024: 37.4)
[14]Wang C*. Radiative-cooling-driven passive thermoelectric devices. Device, 2: 100424, 2024.
[15]Wang C*, Yin Z, Liu J*. Theory and application of temporal coupling mode for a SiC/CaF2/Ag cell-based grating. Optics Letters, 49(20): 5945-5948, 2024.
[16]Liu J*, Li Z, Yu L, Huo Y, Chen H, Wang C*, Wang N, Jiang L, Zhao Y*. Tuning nanochannel microenvironments of a thermoresponsive MXene membrane for mixed molecules gradient separation. Nano Letters, 24(41): 12955-12963, 2024. (一区TOP, IF2024: 9.6)
[17]Liu Yi#, Xie Y#, Chen H#, Liao J, Lu Y, Lan D, Wang C*. Design and experimental study of a compact thermoelectric device driven by solar heating and radiative cooling. Next Energy, 4: 100146, 2024.
[18]Chen Z, Dong M, Wang C*. Passive interfacial photothermal evaporation and sky radiative cooling assisted all-day freshwater harvesting: System design, experiment study, and performance evaluation, Applied Energy, 355: 122254, 2024. (一区TOP, IF2024: 10.1)
[19]Wang C*, Bian H, Jiang Z. Multiple surface polariton-enhanced near-field radiative heat transfer between layered graphene/porous SiC terminals, International Journal of Heat and Mass Transfer, 220: 124991, 2024.
[20]Wang C*, Liu M, Jiang Z. Visible-to-near-infrared asymmetric transmission through a cross grating. Journal of Quantitative Spectroscopy and Radiative Transfer, 315: 108899, 2024.
[21]Feng Y, Wang C*. Lattice Boltzmann study on magnetohydrodynamic double-diffusive convection in Fe3O4-H2O nanofluid-filled porous media. Case Studies in Thermal Engineering, 58: 104405, 2024.
[22]Ymeli GL, Feng Y, Wang C*. Lattice Boltzmann simulations on transient radiative transfer problems in irregular geometries with constant or graded refractive index, International Journal of Thermal Sciences, 197: 108750, 2024.
[23]Wang C*, Liu M, Pan C, Jiang Z. Broadband directional thermal radiator with flexible intensity-directivity tunability in the whole visible spectrum. Applied Physics Letters, 123: 022203, 2023.
[24]Wang C*, Chen H, Jiang Z, Zhang X, Wang F†. Modelling and performance evaluation of a novel passive thermoelectric system based on radiative cooling and solar heating for 24-hour power generation, Applied Energy, 331: 120425, 2023. (一区TOP, IF2023: 11.2)
[25]Wang C*, Chen H, Jiang Z, Zhang X. Design and experimental validation of an all-day passive thermoelectric system via radiative cooling and greenhouse effects, Energy, 263: 125735, 2023. (一区TOP, IF2023: 9.0)
[26]Wang C*, Bian H, Pan C, Jiang Z. Near-field thermal rectification via an InSb/graphene/3C-SiC-nanowire heterostructure, International Journal of Thermal Sciences, 194: 108581, 2023.
[27]Wang C*, Zhang X, Pan C, Jiang Z. Unified discontinuous Galerkin finite element framework for conjugated radiation-conduction heat transfer. Physical Review E, 107, 045303, 2023.
[28]Ymeli GL, Wang C*. Generalized lattice Boltzmann method for radiative transfer problem in slab and irregular graded-index media, Physical Review E, 107: 015302, 2023.
[29]Zhang X, Wang C*. Development and application of discontinuous Galerkin method for solidification problems in a semitransparent medium-filled cavity, Journal of Energy Storage, 71: 108023, 2023.
[30]Ymeli GL, Liu X, Arantes F, Wang C*. Lattice Boltzmann method for radiative transfer in two-layered slab with graded-index and Fresnel reflecting surfaces, International Communications in Heat and Mass Transfer, 148: 107025, 2023.
[31]Ymeli GL, Liu X, Tapimo R, Wang C*. Transient radiative transfer in two graded-index slabs adhered by an infinitely thin vacuum via the lattice Boltzmann method, International Journal of Heat and Mass Transfer, 211: 124228, 2023.
[32]Yadava M, Yadava RS, Wang C*. Lattice Boltzmann simulations of flow inside a converging and diverging nozzle with the insertion of single and multiple circular cylinders, Physics of Fluids, 35: 084110, 2023.
[33]Fokou A, Tchinda R, Ymeli GL, Lazard M, Wang C*. Estimating of the radiance in atmosphere-ocean systems with different atmosphere models by discrete spherical harmonics method, ASME Journal of Heat and Mass Transfer, 145: 052802, 2023.
[34]Wang C*, Liu M, Jiang Z. TiO2 particle agglomeration impacts on radiative cooling films with a thickness of 50 μm, Applied Physics Letters, 121 (20): 121, 202204, 2022.
[35]Wang C*, Chen H, Jiang Z, Zhang X. Refractive index impacts on polarized signals from a homogeneous Rayleigh scattering medium exposed to oblique irradiation. International Communications in Heat and Mass Transfer, 139: 106434, 2022.
[36]Wang C*, Zhang X, Jiang Z. Discontinuous finite element method for transient conductive heat transfer in layered media with thermal contact resistance, International Communications in Heat and Mass Transfer, 138: 106344, 2022.
[37]Wang C*, Liu Z, Jiang Z, Zhang X. Double-diffusive convection in a magnetic nanofluid-filled porous medium: Development and application of a non-orthogonal lattice Boltzmann model, Physics of Fluids, 34 (6): 062012, 2022.
[38]Wang C*, Liu Z, Jiang Z, Zhang X. Numerical investigations of convection heat transfer in a thermal source-embedded porous medium via a lattice Boltzmann method. Case Studies in Thermal Engineering, 30: 101758, 2022.
[39]Feng Y, Wang C*, Xiang Y*, Zhang X. Internal thermal source effects on convection heat transfer in a two-dimensional porous medium: A lattice Boltzmann study. International Journal of Thermal Sciences, 173: 107416, 2022.
[40]Feng Y, Wang C *. On the performance of a MRT lattice Boltzmann algorithm for transient radiative transfer problems. International Communications in Heat and Mass Transfer, 128: 105628, 2021.
[41]Wei L, Li G, Wang C*, Zhang W. Determination of gradient index based on laser beam deflection by stochastic particle swarm optimization, Applied Physics B, 127: 131, 2021.
[42]Wei L, Li G, Song M, Wang C*. Study on dynamic thermal behavior of PCM-filled double glazing unit under solar irradiation, International Journal of Energy Research, 11: 20672-20685, 2021.
[43]陈浩,王存海*,程子明,魏琳扬,王富强,张欣欣.基于辐射制冷-温室效应的热电系统性能分析.物理学报, 70(21): 214401, 2021.
[44]Wang C*, Wu X, Wang F, Zhang X. Optimization design of a multilayer structure for broadband and direction-selective emissivity. ES Energy & Environment, 11: 84-92, 2021.
[45]Feng Y, Wang C*. Discontinuous finite element method applied to transient pure and coupled radiative heat transfer. International Communications in Heat and Mass Transfer, 122: 105156, 2021.(ESI高被引论文)
个人Research Gate主页:https://www.researchgate.net/profile/Cun_Hai_Wang
北京科技大学教师主页:
http://faculty.ustb.edu.cn/wangcunhai/zh_CN/zdylm/195312/list/index.htm
[1]Fan Y, Chen H, Liu X, Zhao Y, Huang Y*, Liu J*, Wang C*. Radiative cooling in outer space: Fundamentals, advances in materials and applications, and perspectives. Advanced Materials, 2505601, 2025. (一区TOP, IF2025: 26.8)
[2]Hou M, Chen H, Li S, Zhang X, Chen J, Jiang Z*, Wang C*, Lai NC*, Ding Y. A tri-mode photothermal, phase-change, and radiative-cooling film for all-day thermoelectric generation. Advanced Materials, 2505601, 2025. (一区TOP, IF2025: 26.8)
[3]Li H, Ma J, Chen H, Hong W*, Lan J, Chang Y, Zhang H, Zhang L, Niu X, Li Y, Liu J*, Wang C*. Interfacial photothermal membrane distillation for direct solar water production. Advanced Functional Materials, e15845, 2025. (一区TOP, IF2025: 19.0)
[4]Chen H, Liu X, Liu J*, Wang F*, Wang C*. Radiative cooling applications for enhanced energy efficiency: System designs, achievements, and outlook. The Innovation, 6: 100999, 2025. (一区TOP, IF2025: 25.7)
[5]Wang C*, Wang W, Chen H, Liu J*, Mimicking scarab beetle elytra in colorful radiative coolers. Matter, 8: 101951, 2025. (一区TOP, IF2024: 18.4)
[6]Wang C*, Chen T, Chen H, Liu J*, Yi H*. Broadband directive thermal emission supported by local surface plasmon and magnetic polaritons. ACS Photonics, 12(4): 2226–2232, 2025. (一区TOP, IF2025: 6.7)
[7]Zhang K, Xie L, Chen Z, Chen H, Wang C*. A high-performance dynamic thermal regulator based on the phase-switchable In3SbTe2. Energy, 325, 15: 136227, 2025. (一区TOP, IF2025: 9.4)
[8]Cheng Chunyun, Jingchong Liu*, Fuqiang Wang*, Cunhai Wang*. Photonic structures in multispectral camouflage: From static to dynamic technologies. Materials Today, 85: 253–281, 2025. (一区TOP, IF2025: 22.0)
[9]Wei J, Chen H, Liu J*, Wang F*, Wang C*. Radiative cooling technologies toward enhanced energy efficiency of solar cells: Materials, systems, and perspectives. Nano Energy, 136, 110680, 2025. (一区TOP, IF2025: 17.1)
[10]Chen H, Wei J, Liu X, Liu J*, Wang C*. Assessing sky radiative cooling power with considering the cloud effects. Applied Thermal Engineering, 278: 127192, 2025.
[11]Chen H, Wang C*. Bridging radiative cooling materials and applications towards alleviating global energy issues. The Innovation Energy, 2: 100090, 2025.
[12]Wang C*, Bian H, Fan D, Zhang P*, Liu J*. Near-field radiative heat transfer between metaterminals composed of SiC plate-supported LiH nanoparticle arrays. International Journal of Heat and Mass Transfer, 236: 126375, 2025.
[13]Wang C*, Chen H, Wang F*. Passive daytime radiative cooling materials toward real-world applications. Progress in Materials Science, 144: 101276, 2024. (ESI高被引, 一区TOP, IF2024: 37.4)
[14]Wang C*. Radiative-cooling-driven passive thermoelectric devices. Device, 2: 100424, 2024.
[15]Wang C*, Yin Z, Liu J*. Theory and application of temporal coupling mode for a SiC/CaF2/Ag cell-based grating. Optics Letters, 49(20): 5945-5948, 2024.
[16]Liu J*, Li Z, Yu L, Huo Y, Chen H, Wang C*, Wang N, Jiang L, Zhao Y*. Tuning nanochannel microenvironments of a thermoresponsive MXene membrane for mixed molecules gradient separation. Nano Letters, 24(41): 12955-12963, 2024. (一区TOP, IF2024: 9.6)
[17]Liu Yi#, Xie Y#, Chen H#, Liao J, Lu Y, Lan D, Wang C*. Design and experimental study of a compact thermoelectric device driven by solar heating and radiative cooling. Next Energy, 4: 100146, 2024.
[18]Chen Z, Dong M, Wang C*. Passive interfacial photothermal evaporation and sky radiative cooling assisted all-day freshwater harvesting: System design, experiment study, and performance evaluation, Applied Energy, 355: 122254, 2024. (一区TOP, IF2024: 10.1)
[19]Wang C*, Bian H, Jiang Z. Multiple surface polariton-enhanced near-field radiative heat transfer between layered graphene/porous SiC terminals, International Journal of Heat and Mass Transfer, 220: 124991, 2024.
[20]Wang C*, Liu M, Jiang Z. Visible-to-near-infrared asymmetric transmission through a cross grating. Journal of Quantitative Spectroscopy and Radiative Transfer, 315: 108899, 2024.
[21]Feng Y, Wang C*. Lattice Boltzmann study on magnetohydrodynamic double-diffusive convection in Fe3O4-H2O nanofluid-filled porous media. Case Studies in Thermal Engineering, 58: 104405, 2024.
[22]Ymeli GL, Feng Y, Wang C*. Lattice Boltzmann simulations on transient radiative transfer problems in irregular geometries with constant or graded refractive index, International Journal of Thermal Sciences, 197: 108750, 2024.
[23]Wang C*, Liu M, Pan C, Jiang Z. Broadband directional thermal radiator with flexible intensity-directivity tunability in the whole visible spectrum. Applied Physics Letters, 123: 022203, 2023.
[24]Wang C*, Chen H, Jiang Z, Zhang X, Wang F†. Modelling and performance evaluation of a novel passive thermoelectric system based on radiative cooling and solar heating for 24-hour power generation, Applied Energy, 331: 120425, 2023. (一区TOP, IF2023: 11.2)
[25]Wang C*, Chen H, Jiang Z, Zhang X. Design and experimental validation of an all-day passive thermoelectric system via radiative cooling and greenhouse effects, Energy, 263: 125735, 2023. (一区TOP, IF2023: 9.0)
[26]Wang C*, Bian H, Pan C, Jiang Z. Near-field thermal rectification via an InSb/graphene/3C-SiC-nanowire heterostructure, International Journal of Thermal Sciences, 194: 108581, 2023.
[27]Wang C*, Zhang X, Pan C, Jiang Z. Unified discontinuous Galerkin finite element framework for conjugated radiation-conduction heat transfer. Physical Review E, 107, 045303, 2023.
[28]Ymeli GL, Wang C*. Generalized lattice Boltzmann method for radiative transfer problem in slab and irregular graded-index media, Physical Review E, 107: 015302, 2023.
[29]Zhang X, Wang C*. Development and application of discontinuous Galerkin method for solidification problems in a semitransparent medium-filled cavity, Journal of Energy Storage, 71: 108023, 2023.
[30]Ymeli GL, Liu X, Arantes F, Wang C*. Lattice Boltzmann method for radiative transfer in two-layered slab with graded-index and Fresnel reflecting surfaces, International Communications in Heat and Mass Transfer, 148: 107025, 2023.
[31]Ymeli GL, Liu X, Tapimo R, Wang C*. Transient radiative transfer in two graded-index slabs adhered by an infinitely thin vacuum via the lattice Boltzmann method, International Journal of Heat and Mass Transfer, 211: 124228, 2023.
[32]Yadava M, Yadava RS, Wang C*. Lattice Boltzmann simulations of flow inside a converging and diverging nozzle with the insertion of single and multiple circular cylinders, Physics of Fluids, 35: 084110, 2023.
[33]Fokou A, Tchinda R, Ymeli GL, Lazard M, Wang C*. Estimating of the radiance in atmosphere-ocean systems with different atmosphere models by discrete spherical harmonics method, ASME Journal of Heat and Mass Transfer, 145: 052802, 2023.
[34]Wang C*, Liu M, Jiang Z. TiO2 particle agglomeration impacts on radiative cooling films with a thickness of 50 μm, Applied Physics Letters, 121 (20): 121, 202204, 2022.
[35]Wang C*, Chen H, Jiang Z, Zhang X. Refractive index impacts on polarized signals from a homogeneous Rayleigh scattering medium exposed to oblique irradiation. International Communications in Heat and Mass Transfer, 139: 106434, 2022.
[36]Wang C*, Zhang X, Jiang Z. Discontinuous finite element method for transient conductive heat transfer in layered media with thermal contact resistance, International Communications in Heat and Mass Transfer, 138: 106344, 2022.
[37]Wang C*, Liu Z, Jiang Z, Zhang X. Double-diffusive convection in a magnetic nanofluid-filled porous medium: Development and application of a non-orthogonal lattice Boltzmann model, Physics of Fluids, 34 (6): 062012, 2022.
[38]Wang C*, Liu Z, Jiang Z, Zhang X. Numerical investigations of convection heat transfer in a thermal source-embedded porous medium via a lattice Boltzmann method. Case Studies in Thermal Engineering, 30: 101758, 2022.
[39]Feng Y, Wang C*, Xiang Y*, Zhang X. Internal thermal source effects on convection heat transfer in a two-dimensional porous medium: A lattice Boltzmann study. International Journal of Thermal Sciences, 173: 107416, 2022.
[40]Feng Y, Wang C *. On the performance of a MRT lattice Boltzmann algorithm for transient radiative transfer problems. International Communications in Heat and Mass Transfer, 128: 105628, 2021.
[41]Wei L, Li G, Wang C*, Zhang W. Determination of gradient index based on laser beam deflection by stochastic particle swarm optimization, Applied Physics B, 127: 131, 2021.
[42]Wei L, Li G, Song M, Wang C*. Study on dynamic thermal behavior of PCM-filled double glazing unit under solar irradiation, International Journal of Energy Research, 11: 20672-20685, 2021.
[43]陈浩,王存海*,程子明,魏琳扬,王富强,张欣欣.基于辐射制冷-温室效应的热电系统性能分析.物理学报, 70(21): 214401, 2021.
[44]Wang C*, Wu X, Wang F, Zhang X. Optimization design of a multilayer structure for broadband and direction-selective emissivity. ES Energy & Environment, 11: 84-92, 2021.
[45]Feng Y, Wang C*. Discontinuous finite element method applied to transient pure and coupled radiative heat transfer. International Communications in Heat and Mass Transfer, 122: 105156, 2021.(ESI高被引论文)
个人Research Gate主页:https://www.researchgate.net/profile/Cun_Hai_Wang
北京科技大学教师主页:
http://faculty.ustb.edu.cn/wangcunhai/zh_CN/zdylm/195312/list/index.htm
专利
1.王存海,陈姿颖,董明宇,等.一种全天候取水装置及取水方法,发明专利.
2.王存海,张禧龙,方悦,等.一种基于辐射制冷-温室效应的温差发电装置,发明专利.
3.王存海,冯岩岩.具有显著方向选择性发射率的多层薄膜结构,发明专利.
4.陈姿颖,董明宇,王存海.一种新型蓄热电式窗帘,实用新型专利.
2.王存海,张禧龙,方悦,等.一种基于辐射制冷-温室效应的温差发电装置,发明专利.
3.王存海,冯岩岩.具有显著方向选择性发射率的多层薄膜结构,发明专利.
4.陈姿颖,董明宇,王存海.一种新型蓄热电式窗帘,实用新型专利.
获奖
指导学生获奖:
1.第十五届全国大学生节能减排社会实践与科技竞赛国家级一等奖,2025.
2.第七届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2025.
3.第六届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2024.
4.第十届全国大学生能源经济学术创意大赛北京市一等奖,2024.
5.硕士研究生国家奖学金、北京科技大学“十佳学术之星”,2023.
6.北京市本科生优秀毕业论文、全国能源动力类百篇本科优秀毕业论文,2023.
7.第十三届挑战杯首都大学生课外学术科技作品竞赛一等奖,2023.
8.第五届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2023.
9.第十五届全国大学生节能减排社会实践与科技竞赛国家级一等奖,2022.
10.第三届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2021.
11.第十一届挑战杯首都大学生课外学术科技作品竞赛一等奖,2021.
12.第十三届全国大学生节能减排社会实践与科技竞赛国家级一等奖,2020.
荣誉称号:
1.北京市青年托举人才,2021.
2.北京科技大学十佳班主任,2022.
1.第十五届全国大学生节能减排社会实践与科技竞赛国家级一等奖,2025.
2.第七届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2025.
3.第六届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2024.
4.第十届全国大学生能源经济学术创意大赛北京市一等奖,2024.
5.硕士研究生国家奖学金、北京科技大学“十佳学术之星”,2023.
6.北京市本科生优秀毕业论文、全国能源动力类百篇本科优秀毕业论文,2023.
7.第十三届挑战杯首都大学生课外学术科技作品竞赛一等奖,2023.
8.第五届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2023.
9.第十五届全国大学生节能减排社会实践与科技竞赛国家级一等奖,2022.
10.第三届北京市大学生节能节水低碳减排社会实践与科技竞赛一等奖,2021.
11.第十一届挑战杯首都大学生课外学术科技作品竞赛一等奖,2021.
12.第十三届全国大学生节能减排社会实践与科技竞赛国家级一等奖,2020.
荣誉称号:
1.北京市青年托举人才,2021.
2.北京科技大学十佳班主任,2022.
代表性科研项目
科研项目:
主持:
1. 国家自然科学基金面上项目,2026.01-2029.12.
2. 北京市自然科学基金交叉融合非共识创新项目,2025.03-2028.02.
3. 中央高校基本科研业务费关键科学技术问题引导项目,2025.07.01-2026.06.30.
3. 国家自然科学基金青年项目,2020.01-2022.12.
4. 中国博士后科学基金面上项目,2019.01-2020.12.
5. 中央高校基本科研业务费, 2018.12-2020.11.
参与:
1. 国家自然科学基金重大项目,生物体内液体/颗粒的流动与迁移及调控机制,2019.01-2023.12.(负责人:张欣欣)
2. 国家自然科学基金创新研究群体项目,热辐射传输与流动控制,2012.01-2017.12.(负责人:谈和平)
3. 国家自然科学基金优青项目,半透明介质能量输运,2015.01-2017.12.(负责人:易红亮)
教学项目:
1. 北京科技大学规划教材项目,《辐射换热基础》,2021.6-2023.6,主持.
2. 北京科技大学精品在线开放课程建设项目,《热工学》,2020.6-2021.6.
在线视频网址:https://www.icourse163.org/course/USTB-1461799172
主持:
1. 国家自然科学基金面上项目,2026.01-2029.12.
2. 北京市自然科学基金交叉融合非共识创新项目,2025.03-2028.02.
3. 中央高校基本科研业务费关键科学技术问题引导项目,2025.07.01-2026.06.30.
3. 国家自然科学基金青年项目,2020.01-2022.12.
4. 中国博士后科学基金面上项目,2019.01-2020.12.
5. 中央高校基本科研业务费, 2018.12-2020.11.
参与:
1. 国家自然科学基金重大项目,生物体内液体/颗粒的流动与迁移及调控机制,2019.01-2023.12.(负责人:张欣欣)
2. 国家自然科学基金创新研究群体项目,热辐射传输与流动控制,2012.01-2017.12.(负责人:谈和平)
3. 国家自然科学基金优青项目,半透明介质能量输运,2015.01-2017.12.(负责人:易红亮)
教学项目:
1. 北京科技大学规划教材项目,《辐射换热基础》,2021.6-2023.6,主持.
2. 北京科技大学精品在线开放课程建设项目,《热工学》,2020.6-2021.6.
在线视频网址:https://www.icourse163.org/course/USTB-1461799172