SbSeI and SbSeBr micro-columnar solar cells by a novel high pressure-based synthesis process

Ivan Caño; Alejandro Navarro-Güell; Edoardo Maggi; Maria Barrio; Josep-Lluís Tamarit; Simon Svatek; Elisa Antolín; Shunya Yan; Esther Barrena; Beatriz Galiana; Marcel Placidi; Joaquim Puigdollers; Edgardo Saucedo

doi:10.1039/d3ta03179a

SbSeI and SbSeBr micro-columnar solar cells by a novel high pressure-based synthesis process

J Mater Chem A Mater. 2023 Jul 20;11(33):17616-17627. doi: 10.1039/d3ta03179a. eCollection 2023 Aug 22.

Authors

Ivan Caño^{1

2}, Alejandro Navarro-Güell^{1

2}, Edoardo Maggi^{1

2}, Maria Barrio³, Josep-Lluís Tamarit^{2

3}, Simon Svatek⁴, Elisa Antolín⁴, Shunya Yan⁵, Esther Barrena⁵, Beatriz Galiana⁶, Marcel Placidi^{1

2}, Joaquim Puigdollers^{1

2}, Edgardo Saucedo^{1

2}

Affiliations

¹ Universitat Politècnica de Catalunya (UPC), Photovoltaic Lab - Micro and Nano Technologies Group (MNT), Electronic Engineering Department, EEBE Av Eduard Maristany 10-14 Barcelona 08019 Catalonia Spain ivan.cano.prades@upc.edu.
² Universitat Politècnica de Catalunya (UPC), Barcelona Centre for Multiscale Science & Engineering Av Eduard Maristany 10-14 Barcelona 08019 Catalonia Spain.
³ Universitat Politècnica de Catalunya (UPC), Group of Characterization of Materials (GCM), Physics Department, EEBE Av Eduard Maristany 10-14 Barcelona 08019 Catalonia Spain.
⁴ Instituto de Energía Solar, Universidad Politécnica de Madrid (UPM) Av. Complutense, 30 Madrid 28040 Spain.
⁵ Institut de Ciència de Materials de Barcelona (ICMAB) Carrer dels Til·lers Bellaterra 08193 Spain.
⁶ Universidad Carlos III de Madrid, Physics Department Av. Universidad 40 Leganés 28911 Spain.

Abstract

Van der Waals chalcogenides and chalcohalides have the potential to become the next thin film PV breakthrough, owing to the earth-abundancy and non-toxicity of their components, and their stability, high absorption coefficient and quasi-1D structure, which leads to enhanced electrical anisotropic properties when the material is oriented in a specific crystalline direction. However, quasi-1D semiconductors beyond Sb₂(S,Se)₃, such as SbSeX chalcohalides, have been scarcely investigated for energy generation applications, and rarely synthesised by physical vapor deposition methodologies, despite holding the promise of widening the bandgap range (opening the door to tandem or semi-transparent devices), and showing enticing new properties such as ferroelectric behaviour and defect-tolerant nature. In this work, SbSeI and SbSeBr micro-columnar solar cells have been obtained for the first time by an innovative methodology based on the selective halogenation of Sb₂Se₃ thin films at pressure above 1 atm. It is shown that by increasing the annealing temperature and pressure, the height and density of the micro-columnar structures grows monotonically, resulting in SbSeI single-crystal columns up to 30 μm, and tuneable morphology. In addition, solar cell prototypes with substrate configuration have shown remarkable V_oc values above 550 mV and 1.8 eV bandgap.