SbSeI and SbSeBr micro-columnar solar cells by a novel high pressure-based synthesis process.
Ivan CañoAlejandro Navarro-GüellEdoardo MaggiMaria BarrioJosep Lluis TamaritSimon SvatekElisa AntolínShunya YanEsther BarrenaBeatriz GalianaMarcel PlacidiJoaquim PuigdollersEdgardo SaucedoPublished in: Journal of materials chemistry. A (2023)
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 Sb 2 (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 Sb 2 Se 3 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.
Keyphrases
- solar cells
- solid state
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- dna damage
- oxidative stress
- magnetic resonance imaging
- liquid chromatography
- magnetic resonance
- climate change
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- dna repair
- risk assessment
- big data
- diffusion weighted imaging
- atomic force microscopy
- artificial intelligence
- high speed
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- finite element