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

Lu, Shuaicheng; Zhao, Yang; Wen, Xixing; Xue, Desheng; Chen, Chao; Li, Kanghua; Kondrotas, Rokas; Wang, Chong; Tang, Jiang

doi:10.1002/solr.201800280

Cited by 48 publications

(18 citation statements)

References 33 publications

(20 reference statements)

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“…Besides, H 2 O 2 treated CdS layer can improve the CdS/Sb 2 (S,Se) 3 heterojunction quality, thereby, enhancing the device PCE from 5.42% for pure CdS to 6.07% in the modified case. [ 77 ]…”

Section: Band Alignment Optimizationmentioning

confidence: 99%

Boosting V_OC of antimony chalcogenide solar cells: A review on interfaces and defects

et al. 2021

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Antimony chalcogenides, including Sb 2 S 3 , Sb 2 Se 3 , and Sb 2 (S,Se) 3 , have been developed as attractive non-toxic and earth-abundant solar absorber candidates among the thin-film photovoltaic devices. Presently, a record certified power conversion efficiency of 10.5% has been demonstrated for antimony chalcogenide solar cells, which is significantly lower than that of Cu 2 (In,Ga)Se 2 (23.35%) and CdTe (22.1%) thin-film solar cells. The inferior performance in antimony chalcogenide solar cells is mainly owing to a large open-circuit voltage (V OC ) deficit resulted from the defect and interface-assisted recombination. Herein, a comprehensive review on the recent advancements interface band alignment and defect passivation are carried out. This review will provide a solid understanding on the interfaces and defects of antimony chalcogenide solar cells, which is beneficial to the research and development of such kind of solar cells.

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Section: Band Alignment Optimizationmentioning

confidence: 99%

Boosting V_OC of antimony chalcogenide solar cells: A review on interfaces and defects

et al. 2021

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“…Studies revealed that Sb 1.9 S 2.2 Se 0.9 has a bandgap of 1.52 eV, falling into the ideal bandgap in the Shockley–Queisser limit. During the publication of the review, a certified PCE of 6.14% and a record efficiency of 6.3% for Sb 2 (S x Se 1−x ) 3 solar cells were realized by using hydrothermal method and VTD method to fabricate Sb 2 (S x Se 1−x ) 3 films, respectively …”

Section: Antimony Chalcogenide Solar Cellsmentioning

confidence: 99%

“…During the publication of the review, a certified PCE of 6.14% and a record efficiency of 6.3% for Sb 2 (S x Se 1Àx ) 3 solar cells were realized by using hydrothermal method and VTD method to fabricate Sb 2 (S x Se 1Àx ) 3 films, respectively. [115,116]…”

Section: Mesoporous Sb 2 (S X Se 1àx ) 3 Sensitized Solar Cellsmentioning

confidence: 99%

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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“…Through impurity incorporation, or an optimized deposition process, the absorber efficiency can be improved to 6.30% and 7.6%, respectively. [ 245–247 ] Another proposed strategy is to build an electric field to separate the electron–hole pairs. Considering the low p‐type conductivity in Sb 2 Se 3 , Chen et al.…”

Section: Pb‐free Ns2‐cation‐containing Semiconductors For Optoelectronic Applicationsmentioning

confidence: 99%

“…Thus, by mapping a series of materials, including PbX (X = S, Se, Te), Sb 2 Te 3 , Bi 2 X 3 (X = Se, Te), and inorganic halide perovskites, into a 2D space with the ES and ET as two coordinates, they found MVB had well‐defined borders to covalent, and iono‐covalent regions, indicating its distinction. [ 229–307 ] Such a map demonstrated that the MVB mechanism approximately possessed one shared electron and moderate electron transfer between adjacent atoms. This predictive model can also give rise to the favorable characteristics in above materials, including large Born effective charge, high optical dielectric constants, strong optical interband transition, etc.…”

Section: Conclusion and Perspectivementioning

confidence: 99%

Alternative Lone‐Pair ns²‐Cation‐Based Semiconductors beyond Lead Halide Perovskites for Optoelectronic Applications

Luo

Wang

et al. 2021

Advanced Materials

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Lead halide perovskites have emerged in the last decade as advantageous high‐performance optoelectronic semiconductors, and have undergone rapid development for diverse applications such as solar cells, light‐emitting diodes , and photodetectors. While material instability and lead toxicity are still major concerns hindering their commercialization, they offer promising prospects and design principles for developing promising optoelectronic materials. The distinguished optoelectronic properties of lead halide perovskites stem from the Pb2+ cation with a lone‐pair 6s2 electronic configuration embedded in a mixed covalent–ionic bonding lattice. Herein, we summarize alternative Pb‐free semiconductors containing lone‐pair ns2 cations, intending to offer insights for developing potential optoelectronic materials other than lead halide perovskites. We start with the physical underpinning of how the ns2 cations within the material lattice allow for superior optoelectronic properties. We then review the emerging Pb‐free semiconductors containing ns2 cations in terms of structural dimensionality, which is crucial for optoelectronic performance. For each category of materials, the research progresses on crystal structures, electronic/optical properties, device applications, and recent efforts for performance enhancements are overviewed. Finally, the issues hindering the further developments of studied materials are surveyed along with possible strategies to overcome them, which also provides an outlook on the future research in this field.

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

Cited by 48 publications

References 33 publications

Boosting V_OC of antimony chalcogenide solar cells: A review on interfaces and defects

Boosting V_OC of antimony chalcogenide solar cells: A review on interfaces and defects

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

Alternative Lone‐Pair ns²‐Cation‐Based Semiconductors beyond Lead Halide Perovskites for Optoelectronic Applications

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

Cited by 48 publications

References 33 publications

Boosting VOC of antimony chalcogenide solar cells: A review on interfaces and defects

Boosting VOC of antimony chalcogenide solar cells: A review on interfaces and defects

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

Alternative Lone‐Pair ns2‐Cation‐Based Semiconductors beyond Lead Halide Perovskites for Optoelectronic Applications

Contact Info

Product

Resources

About

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

Boosting V_OC of antimony chalcogenide solar cells: A review on interfaces and defects

Boosting V_OC of antimony chalcogenide solar cells: A review on interfaces and defects

Alternative Lone‐Pair ns²‐Cation‐Based Semiconductors beyond Lead Halide Perovskites for Optoelectronic Applications