教师名录
陈震,金年会信誉至上青年首席教授。
Website: https://sites.google.com/site/zchen0203/
ORCID: https://orcid.org/0000-0002-5422-8807
Google Scholar: https://scholar.google.com/citations?user=qKZKCIgAAAAJ
2016年入选中央组织部人才计划青年项目,2017年入选江苏省双创人才,2018年获江苏省六大人才高峰资助。陈震于2011年获得教育部中国留学基金委颁发的“优秀自费留学生”奖,并于2014年取得加州大学伯克利分校(University of California, Berkeley)机械工程系能源科学与技术方向博士学位,此后在斯坦福大学应用物理系Ginzton实验室从事博士后研究。现阶段研究兴趣主要包括:1)基本能量载子(声子、电子、光子、分子)在纳米尺度下的传输、存储、转化机理;2)纳米材料、纳米器件在新能源相关产业中的实际应用;3)纳米光子学对辐射传热的控制;4)多层薄膜材料的热物性测试,芯片散热等。主要成果以第一作者身份分别发表在了《Joule》,《Nature Communications》, 《Nature Nanotechnology》, 《Nano Letters》, 《Physical Review B》, 《Applied Physics Letters》等国际顶尖期刊上,文章SCI他引超过3000次(Google Scholar)。陈震教授于2016年和2018年底分别发表在《Nature Communication》和《Joule》上的关于利用宇宙超低温背景散热的论文引发了全球新一轮的绿色能源热,被全球多个媒体报道,包括英国的New Scientists,德国的Welt Der Physik,美国的Science Daily,世界顶尖学术杂志Cell Press以及中国知网,雅虎(Yahoo)科技频道和商业频道等。
2021年1月——至今 金年会信誉至上青年首席教授 2019年6月——至今 金年会信誉至上机械学院 副院长(分管研究生培养、国际合作) 2016年9月——至今 金年会信誉至上机械学院 教授,博导 2015年1月——2018年6月 斯坦福大学 博士后 2014年6月——2015年1月 加州大学伯克利分校 博士后 |
本科生课程:《热工基础》,《能源与纳米科技》(吴健雄学院课程),《微流体与纳米传热》
研究生课程:《Heat Transfer Physics》,《高等传热学》
Science
Joule
Nature Sustainability
Nano Energy
Nano Letters
Physical Review B
Applied Physics Letters
Journal of Applied Physics
Review of Scientific Instruments
ACS Photonics
Optics Express
ACS Applied Materials & Interfaces
Scientific Reports
Advanced Energy Materials
Physica Status Solidi A
IEEE Transactions on Nanotechnology
Solar Rapid Research Letters
Beilstein Journal of Nanotechnology
Journal of Vacuum Science and Technology
2. 江苏省真空协会会员
1. Committee member of K-9 (Heat Transfer Division of ASME)
1. 江苏省双创人才(2018年)
2. 斯坦福大学“全球环境与能源项目”(GCEP)最佳墙报提名奖(2017年)
3. 第十二批中央组织部人才引进计划入选专家(2016年)
4. 加州大学伯克利分校“GraduateDivision Block Grant”(2012年、2014年)
5. 美国国家自然基金委和机械工程师协会“Workshop Grant”(2013年)
6. 中国留学基金委“国家优秀自费留学生奖学金”(2011年)
7. 江苏省“优秀硕士毕业论文”(2007年)
8. 江苏省“优秀学生干部”(2004年)
9. “茅以升奖学金”(2003年)
10. 金年会信誉至上“校长奖学金”(2001年、2002年、2003年)
英文专著 Invited Books 1. Z. Chen and C. Dames, Applied Thermal Measurements at the Nanoscale, in Lessons from Nanoscience: A Lecture Notes Series, ed. M. Lundstrom, World Scientific Publishing Co. (2018).
期刊论文 Refereed Journal Publications Overall citation is over 3,000 according to Google Scholar (http://scholar.google.com/citations?user=qKZKCIgAAAAJ&hl=en) 20. M. Dong, L. Zhu, S. Fan, and Z. Chen, "Concentrated radiative cooling and its constraint from reciprocity," Optics Express 30, 275-285 (2022). (highlighted as an Editor's Pick) 19. Z. Zhang, K. Chen, S. Fan, and Z. Chen, “Shockley-Queisser analysis of the temperature-efficiency correlation of solar cells in the presence of non-radiative heat transfer,” Optics Express 29, 27554-27561 (2021). Erratum: There is a typographical error in the published verison of Fig. 2. The correct title of the x-axis of Fig. 2c-d is: Effective Absorptivity in regime II. 18. M. Westwood, X. Zhao, Z. Chen (co-corresponding author) and C. Dames, “4-fold enhancement in energy scavenging from fluctuating thermal resources using a temperature-doubler circuit,” Joule 5, 2223-2240 (2021). 17. L. Li, L. Zhang, L. Zhang, Y. Zhong, Evelyn N. Wang, Z. Chen (co-corresponding author),and L. Guo, “Sub-Picosecond Optical Response of Metals Due to Non-Thermalized Electron Dynamics”, ES Energy & Environment 11, 19-27 (2021). 16. W. Li, M. Dong, L. Fan, J. J. John, Z. Chen, and S. Fan, “Nighttime Radiative Cooling for Water Harvesting from Solar Panels,” ACS Photonics 8, 269–275 (2021). 15. N. Chen, T. Li, Y. Wang, L. Pan, W. Bao, and Z. Chen, “Generalized “Slope Method” of the 3ω Analysis to Measure the Thermal Conductivity and Heat Capacity of Solids: Frequency- vs. Current-sweep”, ES Energy & Environment10, 13-21 (2020). 14. M. Dong, Z. Zhang, Y. Shi, X. Zhao, S. Fan, and Z. Chen, “Fundamental Limits of the Dew-harvesting Technology,”Nanoscale and Microscale Thermophysical Engineering 24(1), 43-52 (2020). (selected as cover image) 13. M. Dong, N. Chen, X. Zhao, S. Fan, and Z. Chen, “Nighttime Radiative Cooling in Hot and Humid Climates,” Optics Express27, 31587-31598 (2019). 12. Z. Chen, L. Zhu, W. Li, and S. Fan, “Simultaneously and Synergistically Harvest Energy from the Sun and Outer Space,” Joule 3, 101-110 (2019). 11. W. Li, Y. Shi, Z. Chen, and S. Fan, “Photonic thermal management of coloured objects,” Nature Communications 9, 4240 (2018). 10. N. H. Thomas, Z. Chen, S. Fan, and A. J. Minnich, “Semiconductor-based Multilayer Selective Solar Absorber for Unconcentrated Solar Thermal Energy Conversion,” Scientific Reports 7, 5362 (2017). 9. J. Kou, Z. Jurado, Z. Chen, S. Fan, and A. Minnich, “Daytime Radiative Cooling Using Infrared Black Bodies,” ACS Photonics 4(3), 626 (2017). 8. Z. Chen, L. Zhu, A. Raman, and S. Fan, “Radiative cooling to deep subfreezing temperatures through a 24-hour day-night cycle,” Nature Communications 7, 13729 (2016). 7. Z. Chen (co-corresponding author) and C. Dames, “An anisotropic model for the minimum thermal conductivity,” Applied Physics Letters 107, 193104 (2015). 6. Z. Chen, Z. Wei, Y. Chen, and C. Dames, Anisotropic Debye model for the thermal boundary conductance, Physical Review B 87, 125426 (2013). 5. W. Bao, K. Myhro, Z. Zhao, Z. Chen, W. Jang, L. Jing, F. Miao, H. Zhang, C. Dames, and C. N. Lau, In situ observation of electrostatic and thermal manipulation of suspended graphene membranes,” Nano Letters 12, 5470 (2012). 4. W. Jang, Z. Chen (co-first author), W. Bao, C. N. Lau, and C. Dames, Thickness-dependent thermal conductivity of encased graphene and ultrathin graphite, Nano Letters 10, 3909 (2010). 3. Z. Chen, W. Jang, W. Bao, C. N. Lau, and C. Dames, Thermal contact resistance between graphene and silicon dioxide, Applied Physics Letters 95, 161910 (2009). 2. W. Bao, F. Miao, Z. Chen, H. Zhang, W. Jang, C. Dames, and C. N. Lau, Controlled ripple texturing of suspended graphene and ultrathin graphite membranes, Nature Nanotechnology 4, 562 (2009). 1. Z. Chen, J. Yang, P. Zhuang, M. Chen, J. Zhu, and Y. Chen, “Thermal conductivity measurement of InGaAs/InGaAsP superlattice thin films,” Chinese Science Bulletin (in English) 51, 2931 (2006).
会议报告 Conference Presentations 21. H. Chen and Z. Chen, “Modeling Anisotropic Thermal Transport in Black-phosphorus-like Materials,” ASME International Mechanical Engineering Congress & Exposition (IMECE), Virtual, November 2021. 20. T. Li and Z. Chen, “A Scattering Matrix Scheme to Model the Periodic Heating Problem in Layered Structures,” ASME International Mechanical Engineering Congress & Exposition (IMECE), Virtual, November 2021. 19. Z. Zhang, K. Chen, S. Fan, and Z. Chen, “Shockley-Queisser Analysis of the Temperature-Efficiency Correlation of Solar Cells in the Presence of Non-Radiative Heat Transfer,” ASME International Mechanical Engineering Congress & Exposition (IMECE), Virtual, November 2021. 18. N. Chen, T. Li, Y. Wang, L. Pan, W. Bao, and Z. Chen, “Generalized “Slope Method” of the 3ω Analysis to Measure k and C of Solids: Frequency- vs. Current-sweep”, ASME Summer Heat Transfer Conference, Virtual, June 2021. 17. M. Dong, L. Zhu, S. Fan, and Z. Chen, “Concentrated Radiative Cooling and Its Constraint from Reciprocity”, ASME Summer Heat Transfer Conference, Virtual, June 2021. 16. M. Dong, Z. Zhang, Y. Shi, X. Zhao, S. Fan, and Z. Chen, “Fundamental Limits of the Dew-Harvesting Technology,” ASME International Mechanical Engineering Congress & Exposition (IMECE), Virtual, November 2020. 15. Z. Chen, “Anisotropic and selective thermal transport,” International Conference on Thermodynamics and Thermal Metamaterials (ThermoMeta), Virtual, August 2020 (Invited). 14. Z. Chen, L. Zhu, W. Li, and S. Fan, “Simultaneously Harvest Energy from the Sun and Outer Space using the same Physical Area,” ASME Summer Heat Transfer Conference, Bellevue, WA, July 2019. 13. M. Dong and Z. Chen, “Radiative Cooling in Hot and Humid Areas,” 6thASME International Conference of Micro/Nanoscale Heat and Mass Transfer (MNHMT), Dalian, China, July 2019. 12. Z. Chen, L. Zhu, W. Li, and S. Fan, “Simultaneously and Synergistically Harvest Energy from the Sun and Outer Space,” ASME International Mechanical Engineering Congress & Exposition (IMECE), Pittsburgh, PA, November 2018. 11. Z. Chen and S. Fan, “Ultrahigh Performance Radiative Cooling: towards large-scale deployment,” Global Climate & Energy Project Research Symposium 2017, Stanford, CA, November 2017 (Poster). 10. J. Kou, Z. Jurado, Z. Chen, S. Fan, and A. J. Minnich, “Daytime Radiative Cooling Using Near-Black Infrared Emitters,” U. S. Department of Energy Energy Frontier Research Centers PI Meeting, Washington, D.C., July 2017 (Poster). 9. Z. Chen, L. Zhu, A. Raman, and S. Fan, “Ultrahigh-Performance Radiative Cooling through a 24-hour Day-night Cycle,” MRS Fall Meeting, Boston, MA, November 2016. 8. Z. Chen L. Zhu, A. Raman, and S. Fan, “Ultrahigh Performance Radiative Cooling,” Global Climate & Energy Project Research Symposium 2016, Stanford, CA, November 2016 (Poster). 7. Z. Chen L. Zhu, A. Raman, and S. Fan, “Ultrahigh Performance Radiative Cooling,” Society of Engineering Science (53rdAnnual Technical Meeting), College Park, Maryland, October 2016. 6. Z. Chen, C. Wong, S. Lubner, S. Yee, J. Miller, W. Jang, C. Hardin, A. Fong, J. Garay, and C. Dames, “A photon thermal diode,” 8th US-Japan Joint Seminar on Nanoscale Transport Phenomena, Santa Cruz, CA, July 2014 (Invited poster presentation). 5. Z. Chen and C. Dames, “An anisotropic model for the minimum thermal conductivity,” ASME International Mechanical Engineering Congress & Exposition (IMECE), San Diego, CA, November 2013. 4. Z. Chen, C. Wong, S. Lubner, S. Yee, J. Miller, C. Hardin, A. Fong, J. Garay, and C. Dames, “Experimental demonstration of ballistic thermal rectification using a phonon-photon analogy,” ASME Summer Heat Transfer Conference, Minneapolis, MN, July 2013. 3. Z. Chen and C. Dames, “An anisotropic Debye model for the thermal boundary conductance,” ASME International Mechanical Engineering Congress & Exposition (IMECE), Denver, CO, November 2011. 2. Z. Chen and C. Dames, “An Anisotropic Debye Model for Thermal Contact Resistance,” MRS Fall Meeting, Boston, MA, November 2010 (Poster). 1. Z. Chen, W. Jang, W. Bao, C. N. Lau, and C. Dames, Heat transfer in encased graphene, ASME Summer Heat Transfer Conference, San Francisco, CA, July 2009. 会议论文 Conference Proceedings 1. Z. Chen, W. Jang, W. Bao, C. N. Lau, and C. Dames, Heat transfer in encased graphene, ASME Summer Heat Transfer Conference, San Francisco, CA, July 2009 |
5. BOEL薄膜材料热物性测试,华为海思横向项目,2019-2020,主持
4. 热传导和热辐射的动态调制:超高开关比热三极管,国家自然基金面上项目,2018-2021,主持
3. 高科技热界面材料基础研究,科技部重点研发项目,2017-2021,参与
2. 从大气中无能耗高效获取饮用水技术,江苏省双创人才计划,2018-2020,主持
1. 中组部国家级人才引进计划,2016-2021,主持
3. 一种基于辐射制冷技术的空气冷却装置,实用新型专利,专利号:CN 210089180 U,授权公告日:2020.2.18
2. Z. Chen, L. Zhu, A. Raman, E. Goldstein, and S. Fan, Ultrahigh-performance Radiative Cooler, U. S. Patent (non-provisional filed July 17, 2017; application #: US15/651,595).
1. W. Li, Y. Shi, Z. Chen, and S. Fan, APPARATUSES AND METHODS INVOLVING THERMALLY TUNED COMPOSITE MATERIAL, International Patent (S18-067 PCT/US2019/025005 (STFD.393PCT)).
