Selective Infrared Energy Harvesting by Nanoparticle Dispersions in Solar Thermal Desalination Systems

J. Hammonds, K. Stancil, O. Adewuyi
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Abstract

A significant portion of the infrared solar spectrum is either unused, or wasted by inefficient solar energy conversion. In this paper, we show that infrared light harvesting can also be accomplished by dispersions of polar nanoparticles. Polar nanoparticle dispersions in a selective absorber may result in Solar Thermal Desalination (STD) systems that aim to maximize the solar-to-heat conversion efficiency by managing the thermal radiative and conduction losses. In noting that irregular dispersions of polar nanoparticles are less costly than regularly spaced nanostructures to manufacture at large scales, we describe the solar absorptivity as a function of a nanoparticle chain model determined emissivity and thermal conductance. The near-field interactions between nanoparticles are explained by modeling the nanoparticles as dispersed electromagnetic dipole oscillations that interact with solar light. An FDTD model of polar nanodispersions near an optical cavity is used to demonstrate infrared harvesting. With this model, we show that the infrared light-harvesting mechanisms of silica nanoparticles involve local and propagating surface phonon polaritons and varying the volume fraction changes radiation transport properties by several orders of magnitude. In discussing STD systems, we demonstrate a potential to use nanoparticle chains to create novel selective absorbers with tunable solar absorptivity.
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纳米粒子分散体在太阳能热脱盐系统中的选择性红外能量收集
红外太阳光谱的很大一部分要么没有使用,要么被低效的太阳能转换浪费了。在本文中,我们证明了红外光收集也可以通过极性纳米粒子的分散来完成。极性纳米粒子在选择性吸收剂中的分散可能导致太阳能热脱盐(STD)系统,该系统旨在通过控制热辐射和传导损失来最大化太阳能到热的转换效率。注意到极性纳米粒子的不规则分散比有规则间隔的纳米结构在大规模制造时成本更低,我们将太阳吸收率描述为纳米粒子链模型决定发射率和热导率的函数。纳米粒子之间的近场相互作用可以通过将纳米粒子建模为与太阳光相互作用的分散的电磁偶极子振荡来解释。利用光学腔附近的极性纳米色散的时域有限差分模型来演示红外捕获。通过该模型,我们发现二氧化硅纳米颗粒的红外光捕获机制涉及局部和传播表面声子极化子,并且改变体积分数会改变几个数量级的辐射输运性质。在讨论STD系统时,我们展示了使用纳米颗粒链来创建具有可调太阳吸收率的新型选择性吸收剂的潜力。
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