近场热辐射的最新研究进展
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摘要
主要从理论数值模拟和近场辐射实验研究的角度介绍了近几年在近场热辐射传热方面的最新研究成果。理论研究的焦点主要集中在石墨烯复合材料、人工加工或合成超材料等方面的传热研究。实验研究的焦点是实验室基于纳米尺度近场热辐射测量的设备制造与方法创新。目前实验上已经实现了最小距离仅为2 nm的极近场热辐射测量。近场热辐射的进一步研究可为热光伏、辐射制冷以及高效能源收集应用提供理论基础。
From the perspective of theoretical numerical simulation and near-field radiation experimental research, the latest research results in near-field thermal radiation heat transfer are introduced. The focus of theoretical research is mainly on heat transfer studies in graphene composites, artificial processing and synthetic metamaterials. The focus of experimental research is on laboratory equipment manufacturing and method innovation based on nanoscale near-field thermal radiation measurements. Very near-field thermal radiation measurements with a minimum distance of only 2 nm have been experimentally implemented. Further research on near-field thermal radiation provides a theoretical basis for thermal photovoltaic, radiant cooling and efficient energy harvesting applications.
From the perspective of theoretical numerical simulation and near-field radiation experimental research, the latest research results in near-field thermal radiation heat transfer are introduced. The focus of theoretical research is mainly on heat transfer studies in graphene composites, artificial processing and synthetic metamaterials. The focus of experimental research is on laboratory equipment manufacturing and method innovation based on nanoscale near-field thermal radiation measurements. Very near-field thermal radiation measurements with a minimum distance of only 2 nm have been experimentally implemented. Further research on near-field thermal radiation provides a theoretical basis for thermal photovoltaic, radiant cooling and efficient energy harvesting applications.
引文
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[2] Novoselov K S,Geim A K,Morozov S V,et al.Electric Field Effect in Atomically Thin Carbon Films [J].Science,2004,306:666--669.
[3] Novoselov K S,Fal′ko V I,Colombo L,et al.A Roadmap for Graphene [J].Nature,2012,490:192--200.
[4] 张春,曾志刚,杨艳,等.近场热辐射研究的最新进展 [J].红外,2010,31(12):1--6.
[5] 吴昊.钨与掺杂硅平板间的近场辐射换热研究 [D].武汉:华中科技大学,2015.
[6] 宋志鑫.VO2薄膜结构的热辐射特性研究 [D].哈尔滨:哈尔滨工业大学,2015.
[7] 张宇鹏.SiC--真空多层膜结构的近场热传输特性 [D].哈尔滨:哈尔滨工业大学,2012.
[8] 吴会海,黄勇,朱克勇.手性超材料和双曲超材料近场热辐射研究 [J].工程热物理学报,2016,37(3):597--601.
[9] 朱克勇,黄勇,吴会海.双曲超材料近场热辐射穿透深度研究 [J].工程热物理学报,2016,37(11):2393--2396.
[10] 白阳.电磁超材料红外热辐射和近场热传输特性 [D].哈尔滨:哈尔滨工业大学,2015.
[11] 刘伟,黄勇,吴会海.石墨烯--六方氮化硼异质结构近场热辐射研究 [J].工程热物理学报,2017,38(12):2665--2669.
[12] 尹格.石墨烯表面等离激元及其在近场热辐射中的应用研究 [D].杭州:浙江大学,2017.
[13] 赵启梅.石墨烯等离激元在近场辐射热传输中的作用研究 [D].南昌:南昌大学,2018.
[14] 周婷.基于石墨烯的多表面耦合的近场热辐射研究 [D].南昌:南昌大学,2018.
[15] 冯冲,唐祯安,余隽.近场热辐射实验测量方法的进展 [J].材料导报,2013,27(5):55--60.
[16] Desutter J,Tang L,Mathieu F.Near-field Radiative Heat Transfer Devices [J].In Press.
[17] St-Gelais R,Zhu L X ,Fan S H,et al.Near-field Radiative Heat Transfer Between Nanostructures in the Deep Sub-wavelength Regime [J].Nature Nanotechnology,2016,11:515--519.
[18] Song B,Ganjeh Y,Sadat S,et al.Enhancement of Near-field Radiative Heat Transfer Using Polar Dielectric Thin Films [J].Nature Nanotechnology,2015,10:253--258.
[19] Kim K,Song B,Fernández-Hurtado V,et al.Radiative Heat Transfer in the Extreme Nearfield [J].Nature,2015,528:387--391.
[20] Tielrooij K J,Hesp N C H,Principi A,et al.Out-of-plane Heat Transfer in Van Der Waals Stacks Through Electron-hyperbolic Phonon Coupling [J].Nature Nanotechnology,2018,13:41--46.
[21] Chen J,Walther J H,Koumoutsakos P.Ultrafast Cooling by Covalently Bonded Graphene-carbon Nanotube Hybrid Immersed in Water [J].Nanotechnology,2016,27:465705.
[22] Wei Y,Berthou S,Lu X B,et al.A Graphene Zener-Klein Transistor Cooled By a Hyperbolic Substrate [J].Nature Nanotechnology,2018,13:47--52.
[23] Zhao B,Chen K F,Buddhiraju S,et al.High-performance Near-field Thermophotovoltaics for Waste Heat Recovery [J].Nano Energy,2017,41:344--350.
[24] Zhao B,Santhanam P,Chen K F,et al.Near-Field Thermophotonic Systems for Low-Grade Waste-Heat Recovery [J].Nano Letters,2018,18:5224--5230.