Molecular Acenes for Light Capture, Conversion, and Storage

IF 14 Q1 CHEMISTRY, MULTIDISCIPLINARY Accounts of materials research Pub Date : 2024-12-19 DOI:10.1021/accountsmr.4c00305
Phillip M. Greißel, Anna-Sophie Wollny, Yifan Bo, Dominik Thiel, René Weiß, Dirk M. Guldi
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Abstract

Efficient photovoltaics (PV) require capturing and converting solar energy across a broad range of energy. Losses due to thermalization and sub-bandgap photons place, however, significant boundaries on the performance of solar cells. For conventional single-junction cells, the theoretical maximum power conversion efficiency is capped at 33%, a constraint known as the detailed balance limit. Realizing the full potential of PVs requires developing novel strategies to overcome this fundamental obstacle. This Account describes the photon-management capabilities of acenes and addresses these fundamental losses en-route toward enhancing PV performances.

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高效的光伏(PV)技术需要捕获和转换各种能量范围的太阳能。然而,热化和亚带隙光子造成的损耗对太阳能电池的性能产生了重大限制。对于传统的单结电池,理论上的最大功率转换效率被限制在 33%,这一限制被称为详细平衡限制。要充分发挥光伏电池的潜力,就必须开发新的策略来克服这一根本障碍。本报告介绍了烯类化合物的光子管理能力,并在提高光伏性能的过程中解决了这些基本损失。
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17.70
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