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Characterization of MoS2:Nb sputtered thin films. An application as hole transport layer in Cu2ZnSnS4/Si tandem solar cells

TitoloCharacterization of MoS2:Nb sputtered thin films. An application as hole transport layer in Cu2ZnSnS4/Si tandem solar cells
Tipo di pubblicazioneArticolo su Rivista peer-reviewed
Anno di Pubblicazione2024
AutoriMalerba, C., Valentini M., Menchini F., Mirabile Gattia Daniele, Salza E., and Mittiga A.
RivistaThin Solid Films
Volume806
Parole chiaveAntireflection coatings, Carrier lifetime, Copper zinc tin sulphides, Doping (additives), Electrodeposition, Epilayers, Epitaxial growth, Field effect transistors, Gallium nitride, Hard facing, Heterojunctions, Hole transport layers, Injection lasers, Intermediate contact, Kesterites, Layered semiconductors, Magnetron sputtering, Molybdenum disulfide, MoS 2, MOS devices, Narrow band gap semiconductors, Nb film, Photoconducting materials, Photoelectric microscopes, Photoelectron spectroscopy, Plating, Power transistors, Quantum well lasers, Selective contacts, Semiconducting gallium compounds, Semiconducting indium phosphide, Semiconducting tellurium compounds, Semiconducting tin compounds, Semiconductor quantum wells, Solar absorbers, Sulphurization, Tandem solar cells, Thioureas, Titanium nitride
Abstract

MoS2:Nb films deposited by radio-frequency magnetron sputtering are investigated in view of their application in infrared (IR)-transparent contacts for tandem photovoltaic devices. This material is already known to give a good electrical contact with p-type chalcogenide semiconductors, which are typically grown onto opaque molybdenum metallic contacts and a MoS2 layer spontaneously forms at the back interface during the on-top semiconductor growth. Our study explores a different approach, which involves the direct growth of IR-transparent MoS2:Nb films via sputtering inside complete photovoltaic devices, like Cu2ZnSnS4 (CZTS)-based single junction solar cells and CZTS/Si tandem devices. Films deposited at different sputtering pressures are compared by analysing their microstructure, morphology, chemical composition, optical and electrical properties. The effects of post-deposition sulfurization treatments are also investigated. We find that MoS2:Nb films deposited at around 0.1 Pa exhibit compactness but show a notable sulfur deficit ([S]/[Mo]≈1.4), a significant sub-bandgap optical absorptance and lack of crystallinity. Increasing the Ar pressure to 1 Pa raises the [S]/[Mo] ratio to 2.2, yielding crystalline films with good IR-transparency, although with a porous morphology. Despite 0.5 wt% Nb-doping of the sputtering target, the as-deposited films demonstrate n-type conductivity likely due to uncontrolled impurities and intrinsic defects. Ultraviolet Photoemission Spectroscopy measurements suggest that films’ work function higher than 5 eV can be obtained with a post-deposition sulfurization, making these materials suitable as Hole Transport Layer in photovoltaic applications. A similar increase in work function is expected in the CZTS/MoS2 junctions, since the sputtered MoS2:Nb films undergo a sulfurization process needed to obtain the overlying polycrystalline CZTS absorber. CZTS solar cells produced with sputtered MoS2 and Transparent Conductive Oxides contacts on glass substrates, despite plagued by severe adhesion problems, show the potentiality to give efficiencies comparable to reference devices with standard Mo back contact. Fabrication of CZTS/Si tandem devices on textured silicon bottom cells yields a maximum efficiency of 4.4 %, primarily hindered by the low quality of the CZTS film on textured substrates. Nonetheless, optoelectronic characterizations based on both spectrophotometric and quantum efficiency measurements confirm a good IR transparency of the MoS2-based intermediate contacts and the desired electrical behaviour. © 2024 The Author(s)

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URLhttps://www.scopus.com/inward/record.uri?eid=2-s2.0-85203829490&doi=10.1016%2fj.tsf.2024.140527&partnerID=40&md5=fe126c6c219ce5e37c0198982828c4a3
DOI10.1016/j.tsf.2024.140527
Citation KeyMalerba2024