Nonreciprocal photonic management for photovoltaic conversion: design and fundamental efficiency limits

IF 1.5 4区 工程技术 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
A. Sergeev, K. Sablon
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引用次数: 3

Abstract

Abstract. Significant progress in the development of nonreciprocal optical components with broken Kirchhoff symmetry paves the way for increasing the photovoltaic (PV) conversion efficiency beyond the Shockley–Queisser limit due to reuse of emitted photons. Recent papers have analyzed the PV converter with several or an infinite number of multijunction cells, in which the cells are coupled via nonreciprocal filters (optical diodes) in such a way that the light emitted by one cell is absorbed by another cell. We proposed and investigated a single cell converter with nonreciprocal external photon recycling, which provided reabsorption and reuse of the emitting light by the same cell. We considered properties of photons in the sunbeam in terms of ergodicity, disorder, energy availability, information entropy, and coherence, and established fundamental limitations imposed by endoreversible thermodynamics on conversion efficiency at maximal power output. Our results show that the nonreciprocal converter with an ideal multijunction cell can approach the Carnot efficiency, whereas operating exactly at the Carnot limit requires an infinite number of photon recycling processes. This requirement resolves the famous thermodynamic paradox of the optical diode because any small dissipation in the cell or optical system enhanced by infinite recycling will stabilize the converter operation below the Carnot limit. We generalized endoreversible thermodynamics to photonic distributions with nonzero chemical potential and derived the limiting efficiency of the nonreciprocal single-junction PV converter. The performance of this converter with available GaAs solar cells was evaluated.
光伏转换的非互易光子管理:设计和基本效率限制
摘要具有破基尔霍夫对称的非互易光学元件的发展取得了重大进展,为提高光伏(PV)的转换效率铺平了道路,由于发射光子的重复使用,光伏转换效率超过了Shockley-Queisser极限。最近的论文分析了具有几个或无限数量的多结电池的PV转换器,其中电池通过非互反滤波器(光学二极管)耦合,这样一个电池发出的光被另一个电池吸收。我们提出并研究了一种具有非互反外光子回收的单细胞转换器,它提供了发射光在同一细胞中的再吸收和再利用。我们从遍历性、无序性、能量可用性、信息熵和相干性等方面考虑了太阳光中光子的特性,并建立了内可逆热力学对最大功率输出时转换效率的基本限制。我们的研究结果表明,理想多结电池的非互反转换器可以接近卡诺效率,而在卡诺极限下工作需要无限次的光子循环过程。这一要求解决了著名的光学二极管热力学悖论,因为无限循环增强的电池或光学系统中的任何小耗散都会使变换器的运行稳定在卡诺极限以下。我们将内可逆热力学推广到具有非零化学势的光子分布,并推导出非互反单结PV转换器的极限效率。利用现有的砷化镓太阳能电池,对该变换器的性能进行了评价。
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来源期刊
Journal of Photonics for Energy
Journal of Photonics for Energy MATERIALS SCIENCE, MULTIDISCIPLINARY-OPTICS
CiteScore
3.20
自引率
5.90%
发文量
28
审稿时长
>12 weeks
期刊介绍: The Journal of Photonics for Energy publishes peer-reviewed papers covering fundamental and applied research areas focused on the applications of photonics for renewable energy harvesting, conversion, storage, distribution, monitoring, consumption, and efficient usage.
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