Nanostructured thermoelectric energy conversion and refrigeration devices

A. Shakouri
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Abstract

Energy consumption in our society is increasing rapidly. A significant fraction of the energy is lost in the form of heat. In this talk we introduce thermoelectric devices that allow direct conversion of heat into electricity. A key requirement to improve the efficiency is to increase the Seebeck coefficient (S) and the electrical conductivity (σ) while reducing the electronic and lattice contributions to thermal conductivity (κe+κL). Some new physical concepts and nanostructures make it possible to modify the trade-offs between the bulk material properties through the changes in the density of states, scattering rates and interface effects on the electron and phonon transport. We will review recent experimental and theoretical results on nanostructured materials of various dimensions: superlattices, nanowires, nanodots, as well as solid-state thermionic power generation devices [1]. Most of the recent success has been in the reduction of lattice thermal conductivity while maintaining good electrical conductivity. Several theoretical and experimental results to improve the thermoelectric power factor (S2σ) and reduce Lorenz number (σ/κe) are presented. Novel metal-semiconductor nanocomposites are developed where the heat and charge transport are modified at the atomic level. Theory and experiment are compared for several III-V and nitride nanocomposites and multilayers [2]. Potential to increase the energy conversion efficiency and bring the cost down to $0.1-0.2/W will be discussed [3]. We also describe how similar principles can be used to make micro refrigerators with cooling power densities exceeding 500 watts per centimeter square [4] in order to selectively remove dynamic hot spots and decrease significantly the requirements for overall cooling of the chip. We also describe some recent advances in nanoscale thermal characterization. Thermoreflectance imaging is used to measure the transient temperature distribution in power transistors. Resolution down to 100ns in time, submicron spatial and 0.1C in temperature are achieved using megapixel CCDs. Finally, the transition between energy and entropy transport in nanoscale devices will be briefly discussed.
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纳米结构热电能量转换和制冷装置
我们社会的能源消耗正在迅速增加。很大一部分能量以热的形式损失掉了。在这次演讲中,我们将介绍热电装置,它可以将热直接转化为电。提高效率的一个关键要求是提高Seebeck系数(S)和电导率(σ),同时降低电子和晶格对导热系数(κe+κL)的贡献。一些新的物理概念和纳米结构使得通过改变态密度、散射率和界面效应对电子和声子输运的影响来改变块体材料特性之间的权衡成为可能。我们将回顾不同维度纳米结构材料的最新实验和理论结果:超晶格、纳米线、纳米点以及固态热离子发电装置[1]。最近的大多数成功都是在保持良好导电性的同时降低了晶格的导热性。给出了提高热电功率因数(S2σ)和降低洛伦兹数(σ/κe)的理论和实验结果。研制了一种新型的金属-半导体纳米复合材料,在原子水平上改变了热输运和电荷输运。理论和实验比较了几种III-V和氮化物纳米复合材料和多层材料[2]。将讨论提高能量转换效率并将成本降至0.1-0.2美元/W的潜力[3]。我们还描述了如何使用类似的原理来制造冷却功率密度超过每平方厘米500瓦的微型冰箱[4],以便有选择地去除动态热点并显着降低对芯片整体冷却的要求。我们还描述了纳米尺度热表征的一些最新进展。利用热反射成像技术测量功率晶体管的瞬态温度分布。使用百万像素的ccd可以实现时间分辨率低至100ns,空间分辨率为亚微米,温度分辨率为0.1C。最后,简要讨论了纳米器件中能量和熵输运之间的转变。
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