Wide angle tolerant solar spectral splitter for lateral tandem solar cells

TL;DR

This paper presents a novel wide-angle tolerant solar spectral splitter designed via inverse methods, improving lateral tandem solar cell efficiency across various incident angles and enabling tailored spectral management for different times of the day.

Contribution

The study introduces an inverse-designed, microstructured spectral splitter that reduces angle dependency and can be customized for specific angular performance in lateral tandem solar cells.

Findings

Enhanced efficiency over a wide range of incident angles.

Ability to tailor device performance for specific oblique angles.

Demonstrated versatility of the inverse design methodology.

Abstract

Maximizing the power conversion efficiency of solar cells plays a crucial role in upscaling solar energy production. Combining two or more solar cells with different bandgaps into a multi-junction tandem solar cells lowers thermalization losses and increases the power conversion efficiency. Whilst the best efficiencies have been achieved by vertically stacking solar cells, the fabrication process is technologically demanding and leads to high production costs. Novel photovoltaic materials such as organic photovoltaics allow solution processing, which enables the cost effective production of lateral multijunctions, where the single subcells are aligned side by side. To fully unlock their optimal performance, lateral tandems require careful light management, redirecting different spectral bands to the corresponding solar cell. So far, solar spectral splitters suffered from a strong angle dependency, which caused a degradation in performance at the slightest deviation from normal incidence. In this contribution, we reduce this limitation and achieve an enhancement in the conversion efficiency across a wide range of incident angles by inverse designing a solar spectral splitter comprised of two free-form microstructured surfaces on the top and bottom of a supporting glass substrate. Moreover, thanks to the versatility of our methodology, we can tailor the angle-dependent functionality of our device. As such, we also design devices that are optimized to provide enhanced performance at certain oblique angles, which correspond to different times of the day, e.g., when the unit price of energy is higher.