Theoretical maximum photogeneration efficiency and performance characterization of InxGa1−xN/Si tandem water-splitting photoelectrodes

Gaudy, Yannick K., Gacevic, Zarko ORCID: https://orcid.org/0000-0003-0552-2169 and Haussener, Sophia ORCID: https://orcid.org/0000-0002-3044-1662 (2020). Theoretical maximum photogeneration efficiency and performance characterization of InxGa1−xN/Si tandem water-splitting photoelectrodes. "APL Materials", v. 8 ; pp.. https://doi.org/10.1063/5.0007034.

Descripción

Título: Theoretical maximum photogeneration efficiency and performance characterization of InxGa1−xN/Si tandem water-splitting photoelectrodes
Autor/es:
Tipo de Documento: Artículo
Título de Revista/Publicación: APL Materials
Fecha: 2020
Volumen: 8
Materias:
ODS:
Palabras Clave Informales: InGaN, photoelectrochemical cells, water splitting
Escuela: E.T.S.I. Telecomunicación (UPM)
Departamento: Ingeniería Electrónica
Grupo Investigación UPM: Dispositivos Semiconductores del ISOM
Licencias Creative Commons: Ninguna

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Resumen

InxGa1−xN is a promising material for flexible and efficient water-splitting photoelectrodes since the bandgap is tunable by modifying the indium content. We investigate the potential of an InxGa1−xN/Si tandem used as a water-splitting photoelectrode. We predict a maximum theoretical photogeneration efficiency of 27% for InxGa1−xN/Si tandem photoelectrodes by computing electromagnetic wave propagation and absorption. This maximum is obtained for an indium content between 50% and 60% (i.e., a bandgap between 1.4 eV and 1.2 eV, respectively) and a film thickness between 280 nm and 560 nm. We then experimentally assess InxGa1−xN photoanodes with the indium content varying between 9.5% and 41.4%. A Mott–Schottky analysis indicates doping concentrations (which effectively represent defect density, given there was no intentional doping) above 8.1 × 1020 cm−3 (with a maximum doping concentration of 1.9 × 1022 cm−3 for an indium content of 9.5%) and flatband potentials between −0.33 VRHE for x = 9.5% and −0.06 VRHE for x = 33.3%. Photocurrent–voltage curves of InxGa1−xN photoanodes are measured in 1M H2SO4 and 1M Na2SO4, and the incident photon-to-current efficiency spectra in 1M Na2SO4. The incident photon-to-current efficiency spectra are used to computationally determine the diffusion length, the diffusion optical number, as well as surface recombination and transfer currents. A maximum diffusion length of 262 nm is obtained for an indium content of 23.5%, in part resulting from the relatively low doping concentration (9.8 × 1020 cm−3 at x = 23.5%). Nevertheless, the relatively high surface roughness (rms of 7.2 nm) and low flatband potential (−0.1 VRHE) at x = 23.5% cause high surface recombination and affect negatively the overall photoelectrode performance. Thus, the performance of InxGa1−xN photoelectrodes appears to be a tradeoff between surface recombination (affected by surface roughness and flatband potential) and diffusion length (affected by doping concentration/defect density). The performance improvements of the InxGa1−xN photoanodes are most likely achieved through modification of the doping concentration (defect density) and reduction of the surface recombination (e.g., by the deposition of a passivation layer and co-catalysts). The investigations of the ability to reach high performance by nanostructuring indicate that reasonable improvements through nanostructuring might be very challenging.

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Más información

ID de Registro: 78341
Identificador DC: https://oa.upm.es/78341/
Identificador OAI: oai:oa.upm.es:78341
URL Portal Científico: https://portalcientifico.upm.es/es/ipublic/item/7473873
Identificador DOI: 10.1063/5.0007034
URL Oficial: https://pubs.aip.org/aip/apm/article/8/7/071111/10...
Depositado por: Zarko Gacevic
Depositado el: 31 Ene 2024 08:52
Ultima Modificación: 12 Nov 2025 00:00