Sb2Se3 Thin‐Film Photovoltaics Using Aqueous Solution Sprayed SnO2 as the Buffer Layer

Lu, Shuaicheng; Zhao, Yang; Chen, Chao; Zhou, Ying; Li, Deng‐Bing; Li, Kanghua; Chen, Wenhao; Wen, Xixing; Wang, Chong; Kondrotas, Rokas; Lowe, Nathan C.; Tang, Jiang

doi:10.1002/aelm.201700329

Cited by 51 publications

(36 citation statements)

References 24 publications

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“…For example, a CdS ETL works best for Sb 2 Se 3 solar cells, and Sb 2 S 3 and Sb 2 (S x Se 1−x ) 3 solar cells based on SnO 2 ETL generally show better performances. It's noted that Sb 2 Se 3 solar cells using an high‐temperature solution processed SnO 2 as an ETL delivered low efficiency compared with those of CdS and ZnO ETLs . Based on our understanding of SnO 2 from previous review papers, we believe the reason for this low efficiency is that high‐temperature processed SnO 2 ETL cannot effectively block holes compared with the low‐temperature processed ETLs, leading to severe interface recombination and shunt paths.…”

Section: Discussionmentioning

confidence: 92%

“…Interfacial Engineering : Interfacial engineering improvements of planar Sb 2 Se 3 solar cells were mainly focused on developing alternative ETLs or highly efficient HTLs. Apart from the widely used CdS, TiO 2 and ZnO ETLs, wide‐bandgap Mg‐doped ZnO and SnO 2 have been demonstrated to work as efficient alternative ETLs for planar Sb 2 Se 3 heterojunction solar cells . Recently, PbS colloidal quantum dot films were used as HTLs for planar Sb 2 Se 3 solar cells, which not only minimizes the carrier recombination loss at the back contact and boosts the carrier transport efficacy but also contributes to the photocurrent by its own near‐infrared absorption …”

Section: Antimony Chalcogenide Solar Cellsmentioning

confidence: 99%

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Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

et al. 2019

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Antimony chalcogenides such as Sb2S3, Sb2Se3, and Sb2(SxSe1−x)3 have emerged as very promising alternative solar absorber materials due to their high stability, abundant elemental storage, nontoxicity, low‐cost, suitable tunable bandgap, and high absorption coefficient. Remarkable achievements have been made in antimony chalcogenide solar cells in the past few decades, with the power conversion efficiency (PCE) currently reaching 9.2%, which is close to the PCE level required for industrial applications. To facilitate the realization of highly efficient antimony chalcogenide solar cells in the future, a comprehensive review of antimony chalcogenide‐based materials and photovoltaic devices is presented. First, the fundamental physical properties and preparation methods of antimony chalcogenide‐based materials are outlined, and then, notable recent developments in antimony chalcogenide‐based photovoltaic devices with various architectures are highlighted. Finally, the most prominent limitations are described, and approaches to achieving remarkable advances in antimony chalcogenide solar cells in the future are provided.

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Section: Discussionmentioning

confidence: 92%

Section: Antimony Chalcogenide Solar Cellsmentioning

confidence: 99%

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

et al. 2019

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“…Materials and device characterization are similar to our previous reports . The morphologies and EDS characterization of Sb 2 (Se 1−x S x ) 3 films were checked by scanning electron microscopy (FEI Nova NanoSEM450, without Pt coating).…”

Section: Methodsmentioning

confidence: 99%

Sb₂(Se_1‐xS_x)₃ Thin‐Film Solar Cells Fabricated by Single‐Source Vapor Transport Deposition

Zhao

Wen

et al. 2019

Solar RRL

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The properties of Sb2(Se1‐xSx)3 alloy films can be continuously tuned by changing its composition, enabling potentially better device efficiency compared to the Sb2S3 or Sb2Se3 counterparts. Fabrication of Sb2(Se1−xSx)3 films with good uniformity and orientation are prerequisites to realize their full potential. Here, pure‐phase and high‐uniformity Sb2(Se1‐xSx)3 absorbers are successfully produced via a vapor transport deposition method employing a single evaporation source. Increasing the travelling distance of vapor particles can improve the morphology and crystallinity of Sb2(Se1‐xSx)3 films, and as a result, compact Sb2(Se1‐xSx)3 films with strong preferential [221] orientation and uniform composition throughout the whole film are obtained. Further, the CdS surface is treated with H2O2 solution and a device with a champion efficiency of 6.30% is obtained, a new efficiency record for Sb2(Se1‐xSx)3 based thin‐film solar cells without a hole‐transporting layer.

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“…It has been demonstrated that the transportation of electrons between the absorber layer and the electron transporting layer can make a great influence on the PCE of Sb 2 (S,Se) 3 thin film solar cells by tuning the band gap offset at the interface . In addition, series works basing on various electron transporting layer have been carried out by Tang's group, which revealed that the selection of a better electron transporting layer for Sb 2 (S,Se) 3 thin film solar cells is very important. But so far few works were carried out on the band gap engineering between Sb 2 (S,Se) 3 absorber layer and n type films.…”

Section: Introductionmentioning

confidence: 99%

Promising Sb₂(S,Se)₃ Solar Cells with High Open Voltage by Application of a TiO₂/CdS Double Buffer Layer

Wang¹,

Wang²,

Chen³

et al. 2018

Solar RRL

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Sb 2 (S,Se) 3 has gathered a lot of attention recently as a promising alternative absorber material. However, the efficiencies of Sb 2 (S,Se) 3 devices are seriously restricted by the low open circuit voltage (V oc ). In this work, Sb 2 (S, Se) 3 devices equipped with a TiO 2 /CdS double buffer layer are prepared by a hydro-thermal method, which aims to overcome the V oc deficit. The obtained average V oc of the devices is 785 mV and the champion efficiency of 5.73% is also achieved with a highest V oc ¼ 792 mV, Jsc ¼ 12.03 mA cm À2 , FF ¼ 60.9%. The improvement of V oc is benefited from the reduced band gap offset after application of the double buffer layer. The non-encapsulated device could keep an average power conversion efficiency of 5.69% after being stored in ambient air over a month. This indicates the great potential of a double buffer layer in new chalcogenide photovoltaic devices.

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Sb₂Se₃ Thin‐Film Photovoltaics Using Aqueous Solution Sprayed SnO₂ as the Buffer Layer

Cited by 51 publications

References 24 publications

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

Sb₂(Se_1‐xS_x)₃ Thin‐Film Solar Cells Fabricated by Single‐Source Vapor Transport Deposition

Promising Sb₂(S,Se)₃ Solar Cells with High Open Voltage by Application of a TiO₂/CdS Double Buffer Layer

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Sb2Se3 Thin‐Film Photovoltaics Using Aqueous Solution Sprayed SnO2 as the Buffer Layer

Cited by 51 publications

References 24 publications

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

Review of Recent Progress in Antimony Chalcogenide‐Based Solar Cells: Materials and Devices

Sb2(Se1‐xSx)3 Thin‐Film Solar Cells Fabricated by Single‐Source Vapor Transport Deposition

Promising Sb2(S,Se)3 Solar Cells with High Open Voltage by Application of a TiO2/CdS Double Buffer Layer

Contact Info

Product

Resources

About

Sb₂Se₃ Thin‐Film Photovoltaics Using Aqueous Solution Sprayed SnO₂ as the Buffer Layer

Sb₂(Se_1‐xS_x)₃ Thin‐Film Solar Cells Fabricated by Single‐Source Vapor Transport Deposition

Promising Sb₂(S,Se)₃ Solar Cells with High Open Voltage by Application of a TiO₂/CdS Double Buffer Layer