用于热光伏系统的近场辐射光谱控制表面结构

为提升近场热光伏发电系统的能源转换效率和发电功率,设计了Ⅲ-Ⅴ族半导体表面的矩形光栅结构,以实现从热发射器到热光伏电池的近场辐射热流选择性调制.使用在近红外波段具有表面等离子体激元特性的掺杂氧化锌作为热发射器,在GaSb热光伏电池表面添加亚微米二维光栅结构,在近场间距下形成与表面波耦合的陷光效应,由此有选择性地增强了电池能带内的光谱辐射热流.有别于以往类似研究中常用的等效近似方法,开展了时域有限差分方法模拟,能够严格考虑周期性结构细节,结合以涨落耗散理论为基础的Langevin方法,直接计算了复杂结构参与的近场辐射传热问题,以此揭示表面结构影响近场辐射传热的物理机理.结果显示使用带表面结构的薄膜GaSb电池,可使辐射热流的光谱峰值达到同温度远场黑体辐射源情况下的2.84倍,且热流增益区集中在波长略短于电池能带的窄波段区间,适应高效率、高功率热光伏系统对辐射传热设计的要求.     

薄膜和半无限大介质间的近场辐射换热研究

研究了硼掺杂硅(记为Si-19)薄膜和半无限大物体(Si-19和SiC)在100 nm真空间距下的近场辐射换热随薄膜厚度的变化。研究结果表明,当半无限大物体和薄膜为相同的Si-19材料时,由于表面波激发并相互耦合,使得近场辐射换热随薄膜的厚度变化比较复杂。当半无限大物体为SiC材料时,由于表面波的耦合遭到破坏以及辐射体的高发射率频率区和吸收体的高吸收率频率区不匹配,导致表面波的激发对不同材料间的近场辐射换热的增强程度降低,因此在相同计算区域内热流密度随厚度的增加单调增加,没有出现极值点。     

Thermal heat radiation,near-field energy density and near-field radiative heat transfer of coated materials

We investigate the thermal radiation and thermal near-field energy density of a metal-coated semi-infinite body for different substrates. We show that the surface polariton coupling within the metal coating leads to an enhancement of the TM-mode part of the thermal near-field energy density when a polar substrate is used. In this case the result obtained for a free standing metal film is retrieved. In contrast, in the case of a metal substrate there is no enhancement in the TM-mode part, as can also be explained within the framework of surface plasmon coupling within the coating. Finally, we discuss the influence of the enhanced thermal energy density on the near-field radiative heat transfer between a simple semi-infinite and a coated semi-infinite body for different material combinations.     

石墨烯/AZO/SiC复合结构的近场辐射换热特性

由于倏逝波贡献,近场辐射换热可以远超黑体辐射定律给出的极限换热热流,对近场辐射换热的调控在近场热光伏及热管理方面有重要的应用前景。石墨烯是一种有潜力的可用于近场辐射换热调控的功能材料。本文研究了由石墨烯、铝掺杂氧化锌(aluminum-doped zinc-oxide,AZO)及SiC构成的多层复合薄膜的近场辐射换热特性。研究发现:"AZO薄膜+SiC基底"结构的频谱辐射热流在SiC的SPhP频域出现谷值,而"SiC薄膜+AZO基底"结构同时在两种表面极化激元的共振频率处出现峰值;覆盖单层石墨烯薄膜对"AZO薄膜+SiC基底"结构的近场辐射换热基本没有影响;而"石墨烯/SiC薄膜/AZO基底"结构却可以同时支持三种表面极化激元,并在调控石墨烯化学势到适当值时,可以有效增强近场换热。本研究有助于理解石墨烯对近场辐射换热的调控特性。     

Near-field radiative heat transfer between macroscopic planar surfaces

Near-field radiation allows heat to propagate across a small vacuum gap at rates several orders of magnitude above that of far-field, blackbody radiation. Although heat transfer via near-field effects has been discussed for many years, experimental verification of this theory has been very limited. We have measured the heat transfer between two macroscopic sapphire plates, finding an increase in agreement with expectations from theory. These experiments, conducted near 300?K, have measured the heat transfer as a function of separation over mm to μm and as a function of temperature differences between 2.5 and 30?K. The experiments demonstrate that evanescence can be put to work to transfer heat from an object without actually touching it.     

纳米光学辐射传热:从热辐射增强理论到辐射制冷应用

热辐射作为一种无处不在的物理现象,对于科学研究和工程应用都具有重要意义.传统上对热辐射的理解主要是基于普朗克定律,它描述了物体通过辐射交换能量的能力.而近年来的研究表明,由于微纳光学材料在尺寸上远小于热辐射峰值波长,它们的热辐射性质往往很大程度上有别于传统黑体辐射理论所描述的宏观物体.更重要的是,微纳光学材料的热辐射性质可以通过改变它们的几何尺寸和微观构型进行定量的优化设计与精确调控.纳米光学材料与辐射制冷效应的结合,给热辐射效应在能源和环境等相关领域的应用提供了极具前景的应用价值.本文首先从热辐射的基本原理和规律出发,介绍纳米结构热辐射增强的发展进程和最新进展,包括二维材料间的近场热辐射机理以及尺寸效应导致的远场热辐射增强;其次,介绍了近年来纳米光学材料在辐射制冷应用中的重大进展,包括可以实现高效日间辐射制冷的各种纳米光学材料设计;最后,进一步介绍了日间辐射制冷的各种实际应用,包括建筑物制冷、冷凝水收集、舒适衣物与太阳能电池降温等.此外,展望了纳米光学材料的辐射制冷技术在推动荒漠生态环境的治理与改造方面的广阔未来.     

Near-field radiative heat transfer between two plane surfaces with one having a dielectric coating

The effect of a dielectric coating on the near-field radiative heat transfer between two plane surfaces is numerically studied in the framework of the fluctuational electrodynamics. The dielectric coating is assumed to be a SiC or SiO₂ film, which is on top of the emitter. The results show that the near-field radiative flux between the plane surfaces can be either diminished or enhanced by the dielectric coating, depending on the thermal radiative properties of the emitter and the receiver. Furthermore, the dielectric coating effect on the near-field radiative flux can be very different from that on the far-field radiative flux. Detailed analysis on the variations of the TE- and TM-wave components of the radiative flux by adding the dielectric coating is provided, along with the physical mechanisms that account for these changes. Dielectric coatings such as SiC and SiO₂ films are widely seen in microelectronic structures and nanofabrication devices. The results obtained in this work should be valuable for further study and nanotechnological applications of near-field radiative heat transfer.     

Loss and heating of particles in small and noisy traps

We derive the life time and loss rate for a trapped atom that is coupled to fluctuating fields in the vicinity of a room-temperature metallic and/or dielectric surface. Our results indicate a clear predominance of near-field effects over ordinary blackbody radiation. We develop a theoretical framework for both charged ions and neutral atoms with and without spin. Loss processes that are due to a transition to an untrapped internal state are included. Received: 28 June 1999 / Revised version: 4 October 1999 / Published online: 10 November 1999     

Frequency-selective near-field radiative heat transfer between photonic crystal slabs: a computational approach for arbitrary geometries and materials

We demonstrate the possibility of achieving enhanced frequency-selective near-field radiative heat transfer between patterned (photonic-crystal) slabs at designable frequencies and separations, exploiting a general numerical approach for computing heat transfer in arbitrary geometries and materials based on the finite-difference time-domain method. Our simulations reveal a tradeoff between selectivity and near-field enhancement as the slab-slab separation decreases, with the patterned heat transfer eventually reducing to the unpatterned result multiplied by a fill factor (described by a standard proximity approximation). We also find that heat transfer can be further enhanced at selective frequencies when the slabs are brought into a glide-symmetric configuration, a consequence of the degeneracies associated with the nonsymmorphic symmetry group.     

Near-field heat transfer: A radiative interpretation of thermal conduction

It is shown in this article that the near-field radiative heat transfer can be interpreted as a conduction heat transfer due to the propagation of polaritons. We consider two situations. In the first one, two heated bodies at different temperatures are separated by a gap and in the second one a temperature gradient is imposed to a bulk material. In both situations, the radiative heat transfer is calculated by means of fluctuational electrodynamics. Asymptotic expressions of a thermal conductivity are obtained from the radiative heat transfer calculation. We interpret this conductivity as a consequence of the heat transfer by propagation and collisions of polaritons.     

Nanostructures fabricated on metal surfaces assisted by laser with optical near-field effects

Nanostructures on metal film surfaces have been written directly using a pulsed ultraviolet laser. The optical near-field effects of the laser were investigated. Spherical silica particles (500–1000 nm in diameter) were placed on metal films. After laser illumination with a single laser shot, nanoholes were obtained at the original position of the particles. The mechanism for the formation of the nanostructure patterns was investigated and found to be the near-field optical resonance effect induced by the particles on the surface. The size of the nanohole was studied as a function of laser fluence and silica particle size. The experimental results show a good agreement with those of the relevant theoretical calculations of the near-field light intensity distribution. The method of particle-enhanced laser irradiation allows the study of field enhancement effects as well as its potentialapplications for nanolithography. Received: 10 December 2002 / Accepted: 20 January 2003 / Published online: 28 May 2003 RID="*" ID="*"Corresponding author. Fax: +65-777/1349, E-mail: HUANG_Sumei@dsi.a-star.edu.sg     

球形粒子的近场辐射换热研究

近场辐射引起的能量交换可以比远场辐射高若干个数量级.本文计算了SiC和Cu两种球形颗粒的近场辐射换热,发现当颗粒间距非常小时,辐射换热会大大强化.颗粒直径、颗粒间距以及颗粒的介电常数是决定近场辐射换热大小的重要因素,而颗粒温度对近场辐射换热的影响较小.     

Role of fluctuational electrodynamics in near-field radiative heat transfer

The objective of this paper is to discuss the role of fluctuational electrodynamics in the context of a generalized radiative heat transfer problem. Near-field effects, including the interference phenomenon and radiation tunneling, are important for applications to nanostructures. The classical theory of radiative transfer cannot be readily applied as the feature size approaches the dominant wavelength of radiative emission. At all length scales, however, propagation of radiative energy is properly represented by the electromagnetic wave approach, which requires the solution of the Maxwell equations. Fluctuational electrodynamics provides a model for thermal emission when solving a near-field radiation heat transfer problem, and the fluctuation-dissipation theorem provides the bridge between the strength of the fluctuations of the charges inside a body and its local temperature. This paper provides a complete and systematic derivation of the near-field radiative heat flux starting from the Maxwell equations. An illustrative example of near-field versus far-field radiation heat transfer is presented, and the length scale for transition from near- to far-field regime is discussed; the results show that this length scale can be as large as three times than predicted from Wien's law.     

Electromagnetic interaction of fluorophores with designed two-dimensional silver nanoparticle arrays

We study the fluorescence enhancement of dye molecules adsorbed on regular two-dimensional arrays of designed silver nanoparticles. The silver particles show two orthogonal optical resonances at different wavelengths because of their elongated shape. The short-wavelength resonance was designed to fit to the absorption maximum of the fluorophore. When the excitation light drives the short-wavelength resonance, the measured fluorescence intensity is strongly enhanced compared to that for the orthogonal particle orientation. This shows directly a strong electromagnetic coupling between the nanoparticles and the fluorophore. Additionally enhanced photochemical bleaching is observed due to the interaction of fluorophores with the particles. Using a rate model describing the fluorescence enhancement and the bleaching enhancement, an average value for the particle-induced increase in the radiative fluorescence rate is obtained, together with a lower limit for the averaged particle-induced field intensity enhancement factor. Received: 3 July 2001 / Revised version: 3 September 2001 / Published online: 15 October 2001     

金纳米棒复合体的消光特性

金属纳米颗粒局域表面等离激元共振时能够产生消光和近场增强效应已经成为国内外研究的热点. 应用时域有限差分法对L形纳米棒与普通纳米棒构成的金纳米棒复合体的消光光谱及其近场增强和电流矢量密度分布进行了研究. 计算结果表明, 普通纳米棒和L形纳米棒二聚体的光谱响应与纳米棒间的间距有关, 而金纳米棒复合体的消光光谱可通过调整L形纳米棒与普通纳米棒间的间距、L形纳米棒的臂长度以及普通纳米棒的长度进行调谐. 此外金纳米棒复合体可以分解成L形纳米棒二聚体和普通纳米棒二聚体两个部分, 通过分别改变L形纳米棒的臂长和普通纳米棒的长度, 对比L形纳米棒二聚体和普通纳米棒二聚体间的共振峰位置变化, 可以更直观地了解金纳米棒复合体消光光谱线型的变化. 这些结果可用于指导金纳米棒复合体纳米光子器件的设计, 以满足其在表面增强拉曼散射和生物传感等方面应用.     

Control of near-field radiative heat transfer via surface phonon–polariton coupling in thin films

The possibility of controlling near-field radiative heat transfer with the use of silicon carbide thin films supporting surface phonon–polaritons in the infrared spectrum is explored. For this purpose, the local density of electromagnetic states is calculated and analyzed within the nanometric gap formed between two SiC films as well as the radiative heat flux exchanged between the thin layers.     

Optical near field scattered by surface defects: Two-dimensional numerical analysis

Recently developed scanning near-field optical microscopy has drawn attention to the problem of describing the electromagnetic field in the close vicinity of a surface. In this work, we present a numerical simulation that solves rigorously the field equations for a dielectric-air-dielectric layer system with arbitrary one-dimensional structure at its interfaces. Our theory is applied to calculate the intensity of the near field transmitted at the center of the tip of a probe as it is moved at a constant height above a surface with two identical topographic defects. The effects on the optical image due to the separation of the objects, and the shape difference between the ridges and grooves are discussed. The resolution limit and the conditions for near field interaction are determined. This paper was originally presented at the first Asia-Pacific Workshop on Near Field Optics, which was held on August 17 and 18, 1996 at Seoul Education and Culture Center, Seoul, Korea, organized by Condensed Matter Research Institute, Seoul National University.     

Role of confined Bloch waves in the near field heat transfer between two photonic crystals

The near field heat transfer between two finite size one-dimensional photonic crystals separated by a small vacuum gap and maintained in nonequilibrium thermal situation is theoretically investigated. The main features of this electromagnetic transfer are discussed and compared with what is generally observed with media that support surface polaritons. It is shown that the presence of surface Bloch waves can significantly enhance heat transfers beyond the far field limit for both polarization states of electromagnetic field at subwavelength separation distances. A specific attention is addressed to the consequence of the slopes of surface Bloch waves dispersion curves on the heat transfer. In particular, it is shown that the localization of surface Bloch waves close to the light line allows to observe a transfer exaltaion at larger separation distances than the Wien wavelength. These results could open new possibilities for the development of innovative near-field technologies such as near-field thermophotovoltaic conversion, plasmon assisted nanophotolitography or near-field spectroscopy.     

瞬态激光脉冲在吸收、发射性介质内引起的温度响应

本文导出了平行光入射辐射穿过半透明界面,在吸收、发射性介质内产生的辐射热源的表达式。数值模拟了瞬间激光脉冲入射下：（1）半透明介质与不透明介质在非人射面上的过余温度响应;（2）入的激光的波长对温度响应的影响;（3）界面光学特性（两侧均为不透明界面,两侧均为半透明界面,一侧为半透明、另一侧为不透明界面）对温度响应的影响;（4）采用Planck、Rosseland平均吸收系数处理非灰介质时,对辐射与导热瞬态耦合换热的影响。     

水雾强弥散条件下高温温场多光谱成像反演

高浓度水雾条件下的表面高温温场反演测量在航空航天、冶金铸造等工业领域有着重要的应用。由于水雾的弥散作用,高温表面的辐射透过水雾后,会出现强烈的衰减和散射,导致传统辐射测温方法出现很大误差。现有水雾弥散条件下的温场反演测量主要包括基于试验数据反推及实时测量水雾参数进行修正的测量方法,并基于辐射传输理论对测量结果进行误差分析和评估,测量方式多为单通道或双通道点辐射测温。基于水雾场红外光谱辐射特性的计算,提出了一种水雾强弥散条件下表面高温温场多光谱成像反演方法;根据辐射传输理论,考虑强弥散条件下的邻近效应,建立了相应的反演模型。在水雾场相关参数未知的情况下,通过三个透过水雾场后的高温目标长波红外光谱辐射图像,反演得到表面高温温场的真温分布。反演第一步是辐射温度场反演,即通过长波红外辐射图像,根据定标曲线和高温目标的光谱发射率先验数据,得到高温目标透过弥散水雾场经过发射率校正的辐射温度场;反演的第二步是根据三通道非线性反演模型,得到目标的真温温场分布。设计了一个长波红外三光谱通道反演测量装置,中心波长分别是8.8, 10.7和12.0 μm,对高温目标进行三个长波红外光谱通道的同时探测成像。设计了一套验证测试装置,利用标准高温黑体源和水雾弥散设备,进行了高温目标水雾弥散条件下的辐射图像采集和目标温度的反演试验。试验结果表明8～14 μm长波红外波段比短波波段对水雾弥散具有更强的抗干扰能力,在1 100和1 200 ℃典型温度点反演的平均误差在7%左右,大大减小了未经校正的辐射传输失真,适用于黑体和灰体高温目标,且无需水雾场的浓度和粒径分布等先验信息,基于多光谱成像信息的水雾弥散条件下温场反演方法具有一定的普适性和创新性。