1. RAINBOW Organic Solar Cells: Implementing Spectral Splitting in Lateral Multi‐Junction Architectures
- Author
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Martí Gibert‐Roca, Miquel Casademont‐Viñas, Quan Liu, Koen Vandewal, Alejandro R. Goñi, Mariano Campoy‐Quiles, Gibert-Roca, Marti/0000-0003-1214-6931, Campoy-Quiles, Mariano/0000-0002-8911-640X, Casademont-Vinas, Miquel/0000-0002-2848-9069, Goni, Alejandro R./0000-0002-1193-3063, Vandewal, Koen/0000-0001-5471-383X, Gibert-Roca, Marti, Casademont-Vinas, Miquel, LIU, Quan, VANDEWAL, Koen, Goni, Alejandro R., Campoy-Quiles, Mariano, Ministerio de Ciencia, Innovación y Universidades (España), Ministerio de Ciencia e Innovación (España), Generalitat de Catalunya, and European Research Council
- Subjects
spectral splitting ,Mechanical Engineering ,Multi-junction ,Ensure access to affordable, reliable, sustainable and modern energy for all ,Tandem ,tandem devices ,Nonfullerene blend ,Mechanics of Materials ,RAINBOW solar cells ,General Materials Science ,Rainbow solar cell ,organic photovoltaics ,multi-junction geometries ,nonfullerene blends - Abstract
While multi-junction geometries have the potential to boost the efficiency of organic solar cells, the experimental gains yet obtained are still very modest. This work proposes an alternative spectral splitting device concept in which various individual semiconducting junctions with cascading band gaps are laid side by side, thus the name RAINBOW. Each lateral sub-cell receives a fraction of the spectrum that closely matches the main absorption band of the given semiconductor. Here, simulations are used to identify the important material and device properties of each RAINBOW sub-cell. Using the resulting design rules, three systems are selected, namely PBDB-T-2F:IO-4Cl, PBDB-T-2F:Y6 and PTB7-Th:COTIC-4F, and their potential as sub-cells in this geometry is experimentally investigated. With the aid of a custom built setup that generates spectrally spread sunlight on demand, the simulations are experimentally validated, showing that this geometry can lead to a reduction in thermalization losses and an improvement in light harvesting, which results in a relative improvement in efficiency of 46.6% with respect to the best sub-cell. Finally, a working proof of concept monolithic device consisting of two sub-cells deposited from solution on the same substrate is fabricated, thus demonstrating the feasibility and the potential of the RAINBOW solar cell concept. This article is protected by copyright. All rights reserved., The Spanish "Ministerio de Ciencia e Innovación (MICINN)" is gratefully acknowledged for its supportthrough grant No. CEX2019-000917-S (FUNFUTURE) in the framework of the Spanish Severo OchoaCentre of Excellence program and the AEI/FEDER(UE) grants PGC2018-095411-B-I00(RAINBOW),TED2021-131911B-I00and PID2021-128924OB-I00(ISOSCELLES). The authors also thank the Cata-lan agency AGAUR for grant2021-SGR-00444. MCV acknowledges a FPI fellowship (PRE2019-089855)from MICINN co-financed by the European Social Fund and MGR acknowledges the scholarship FPU16/02631 from the Spanish "Ministerio de Educación". MCV and MGR also thank the PhD programme in Materi-als Science from Universitat Autònoma de Barcelona in which both were enrolled. KV and QL acknowl-edge funding by the European Research Council (ERC, grant agreement864625)., With funding from the Spanish government through the ‘Severo Ochoa Centre of Excellence’ accreditation (CEX2019-000917-S).
- Published
- 2023