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Part 1: Document Description
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Citation |
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Title: |
Replication Data for: Highly Efficient Thermally Co-evaporated Perovskite Solar Cells and Mini-modules |
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Identification Number: |
doi:10.21979/N9/TVMWCH |
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Distributor: |
DR-NTU (Data) |
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Date of Distribution: |
2021-03-29 |
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Version: |
1 |
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Bibliographic Citation: |
Lim, Jia Wei Melvin, 2021, "Replication Data for: Highly Efficient Thermally Co-evaporated Perovskite Solar Cells and Mini-modules", https://doi.org/10.21979/N9/TVMWCH, DR-NTU (Data), V1 |
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Citation |
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Title: |
Replication Data for: Highly Efficient Thermally Co-evaporated Perovskite Solar Cells and Mini-modules |
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Identification Number: |
doi:10.21979/N9/TVMWCH |
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Authoring Entity: |
Lim, Jia Wei Melvin (Nanyang Technological University) |
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Software used in Production: |
Origin |
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Grant Number: |
under Energy Innovation Research Program NRF2015EWT-EIRP003-004 |
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Grant Number: |
under Energy Innovation Research Program NRF-CRP14-2014-03 |
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Grant Number: |
Tier 2 grant MOE2017-T2-1-110 |
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Grant Number: |
Investigatorship Programme NRF-NRFI-2018-04 |
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Distributor: |
DR-NTU (Data) |
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Access Authority: |
Lim Jia Wei Melvin |
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Depositor: |
Lim Jia Wei Melvin |
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Date of Deposit: |
2021-03-29 |
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Holdings Information: |
https://doi.org/10.21979/N9/TVMWCH |
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Study Scope |
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Keywords: |
Earth and Environmental Sciences, Physics, Earth and Environmental Sciences, Physics, perovskite, solar cells |
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Abstract: |
The rapid improvement in the power conversion efficiency (PCE) of perovskite solar cells (PSCs) has prompted interest in bringing the technology toward commercialization. Capitalizing on existing industrial processes facilitates the transition from laboratory to production lines. In this work, we prove the scalability of thermally co-evaporated MAPbI3 layers in PSCs and mini-modules. With a combined strategy of active layer engineering, interfacial optimization, surface treatments, and light management, we demonstrate PSCs (0.16 cm2 active area) and mini-modules (21 cm2 active area) achieving record PCEs of 20.28% and 18.13%, respectively. Un-encapsulated PSCs retained 90% of their initial PCE under continuous illumination at 1 sun, without sample cooling, for more than 100 h. Looking toward tandem and building integrated photovoltaic applications, we have demonstrated semi-transparent mini-modules and colored PSCs with consistent PCEs of ~16% for a set of visible colors. Our work demonstrates the compatibility of perovskite technology with industrial processes and its potential for next-generation photovoltaics. |
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Kind of Data: |
Raw Data |
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Notes: |
Data for Figures 1D and E only |
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Methodology and Processing |
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Sources Statement |
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Data Access |
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Other Study Description Materials |
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Related Publications |
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Citation |
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Identification Number: |
10.1016/j.joule.2020.03.005 |
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Bibliographic Citation: |
Li, J., Wang, H., Chin, X. Y., Dewi, H. A., Vergeer, K., Goh, T. W., . . . Bruno, A. (2020). Highly efficient thermally co-evaporated perovskite solar cells and mini-modules. Joule, 4(5), 1035-1053. |
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Citation |
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Identification Number: |
10356/141615 |
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Bibliographic Citation: |
Li, J., Wang, H., Chin, X. Y., Dewi, H. A., Vergeer, K., Goh, T. W., . . . Bruno, A. (2020). Highly efficient thermally co-evaporated perovskite solar cells and mini-modules. Joule, 4(5), 1035-1053. |
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Label: |
Fig 1D & E.rar |
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Text: |
Raw data for Figure 1D and E in the manuscript |
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Notes: |
application/x-rar-compressed |