Open AccessMaterials interface engineering for solution-processed photovoltaics
Author(s) -
Michael Gräetzel,
Raj René Janssen,
David B. Mitzi,
Edward H. Sargent
Publication year - 2012
Publication title -
nature
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 15.993
H-Index - 1226
eISSN - 1476-4687
pISSN - 0028-0836
DOI - 10.1038/nature11476
Subject(s) - photovoltaics , nanometre , materials science , flexibility (engineering) , solar cell , nanotechnology , grain boundary , charge carrier , optoelectronics , energy conversion efficiency , photovoltaic system , engineering physics , electrical engineering , physics , engineering , microstructure , statistics , mathematics , composite material , metallurgy
Advances in solar photovoltaics are urgently needed to increase the performance and reduce the cost of harvesting solar power. Solution-processed photovoltaics are cost-effective to manufacture and offer the potential for physical flexibility. Rapid progress in their development has increased their solar-power conversion efficiencies. The nanometre (electron) and micrometre (photon) scale interfaces between the crystalline domains that make up solution-processed solar cells are crucial for efficient charge transport. These interfaces include large surface area junctions between photoelectron donors and acceptors, the intralayer grain boundaries within the absorber, and the interfaces between photoactive layers and the top and bottom contacts. Controlling the collection and minimizing the trapping of charge carriers at these boundaries is crucial to efficiency.
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