Reality and perfection of China's addressing climate change legislation in post-Paris Agreement era
In: International environmental agreements: politics, law and economics, Band 23, Heft 3, S. 311-331
ISSN: 1573-1553
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In: International environmental agreements: politics, law and economics, Band 23, Heft 3, S. 311-331
ISSN: 1573-1553
In: MEMSCI-D-22-00039
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Working paper
In: PBFJ-D-22-00206
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In: JOULE-D-23-00805
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Carbon-based electrodes represent a promising approach to improve stability and up-scalability of perovskite photovoltaics. The temperature at which these contacts are processed defines the absorber grain size of the perovskite solar cell: in cells with low-temperature carbon-based electrodes (L-CPSCs), layer-by-layer deposition is possible, allowing perovskite crystals to be large (>100 nm), while in cells with high-temperature carbon-based contacts (H-CPSCs), crystals are constrained to 10-20 nm size. To enhance the power conversion efficiency of these devices, the main loss mechanisms were identified for both systems. Measurements of charge carrier lifetime, quasi-Fermi level splitting (QFLS) and light-intensity-dependent behavior, supported by numerical simulations, clearly demonstrate that H-CPSCs strongly suffer from non-radiative losses in the perovskite absorber, primarily due to numerous grain boundaries. In contrast, large crystals of L-CPSCs provide long carrier lifetime (1.8 µs) and exceptionally high QFLS of 1.21 eV for an absorber bandgap of 1.6 eV. These favorable characteristics explain the remarkable open-circuit voltage (VOC) of over 1.1 V in hole-selective layer-free L-CPSCs. However, the low photon absorption and poor charge transport in these cells limit their potential. Finally, effective strategies are provided to reduce non-radiative losses in H-CPSCs, transport losses in L-CPSCs and to improve photon management in both cell types. ; This work has been partially funded within the projects PROPER financed from the German Ministry of Education and Research under funding number 01DR19007 and UNIQUE supported under umbrella of SOLAR-ERA.NET_cofund by ANR, PtJ, MIUR, MINECO-AEI and SWEA, within the EU's HORIZON 2020 Research and Innovation Program (cofund ERA-NET Action No. 691664). D. B. acknowledges the scholarship support of the German Federal Environmental Foundation (DBU) and S. Z. acknowledges the scholarship support of the German Academic Exchange Service (DAAD). B.Y. and A.Ha. acknowledge the funding from the European Union's Horizon 2020 research and innovation program ESPRESSO under the agreement No.: 764047. This work has also been partially funded by Swiss National Science Foundation with Project No. 200020_185041. T.D. acknowledges a National University of Ireland Travelling Studentship. K.F. acknowledges a George and Lilian Schiff Studentship, Winton Studentship, the Engineering and Physical Sciences Research Council (EPSRC) studentship, Cambridge Trust Scholarship, and Robert Gardiner Scholarship. S.S. acknowledges support from the Royal Society and Tata Group (UF150033). M.A. acknowledges funding from the European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreement No.841386. The authors would like to thank Maryamsadat Heydarian and Laura Stevens for their EQE and AFM measurements. The authors thank the EPSRC (EP/R023980/1) for funding.
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Making large datasets findable, accessible, interoperable and reusable could accelerate technology development. Now, Jacobsson et al. present an approach to build an open-access database and analysis tool for perovskite solar cells. Large datasets are now ubiquitous as technology enables higher-throughput experiments, but rarely can a research field truly benefit from the research data generated due to inconsistent formatting, undocumented storage or improper dissemination. Here we extract all the meaningful device data from peer-reviewed papers on metal-halide perovskite solar cells published so far and make them available in a database. We collect data from over 42,400 photovoltaic devices with up to 100 parameters per device. We then develop open-source and accessible procedures to analyse the data, providing examples of insights that can be gleaned from the analysis of a large dataset. The database, graphics and analysis tools are made available to the community and will continue to evolve as an open-source initiative. This approach of extensively capturing the progress of an entire field, including sorting, interactive exploration and graphical representation of the data, will be applicable to many fields in materials science, engineering and biosciences. ; Funding Agencies|European UnionEuropean Commission [841386, 795079, 840751, 787289, 764787, 756962, 764047, 850937]; Helmholtz-Zentrum Berlin fur Materialien und Energie; Cambridge India Ramanujan Scholarship; China Scholarship CouncilChina Scholarship Council; Deutscher Akademischer Austauschdienst (DAAD)Deutscher Akademischer Austausch Dienst (DAAD); EPSRCUK Research & Innovation (UKRI)Engineering & Physical Sciences Research Council (EPSRC) [EP/S009213/1]; GCRF/EPSRC SUNRISEUK Research & Innovation (UKRI)Engineering & Physical Sciences Research Council (EPSRC) [EP/P032591/1]; German Federal Ministry for Education and Research (BMBF)Federal Ministry of Education & Research (BMBF) [03XP0091, ZT-0024, 03SF0540, 03SF0557A]; Helmholtz Energy Materials Foundry; The Helmholtz Innovation Laboratory HySPRINT; HyPerCells graduate school; Helmholtz AssociationHelmholtz Association; Helmholtz International Research School (HI-SCORE); Erasmus programme (CDT-PV) [EP/L01551X/1]; European Unions Horizon 2020 research and innovation programme (Marie Sklodowska-Curie grant) [841386, 795079, 840751]; Royal Society University Research FellowshipRoyal Society of London [UF150033]; SNaPSHoTs (BMBF)Federal Ministry of Education & Research (BMBF); SPARC II; German Research Foundation (DFG)German Research Foundation (DFG) [SPP2196]; National Natural Science Foundation of ChinaNational Natural Science Foundation of China (NSFC) [51872014]; Recruitment Programme of Global Experts; Fundamental Research Funds for the Central UniversitiesFundamental Research Funds for the Central Universities; 111 projectMinistry of Education, China - 111 Project [B17002]; US Department of Energys Office of Energy Efficiency and Renewable Energy under Solar Energy Technologies Office (SETO) agreementUnited States Department of Energy (DOE) [DE-EE0008551]; Colombia Scientific Programme [FP44842-218-2018]; committee for the development of research (CODI) of the Universidad de Antioquia [2017-16000]; Spanish MINECOSpanish Government [SEV-2015-0522]; Swedish research council (VR)Swedish Research Council [2019-05591]; Swedish Energy AgencySwedish Energy AgencyMaterials & Energy Research Center (MERC) [2020-005194]
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