| "Plastic" solar cells: self-assembly of bulk heterojunction nanomaterials by spontaneous phase separation. | |
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MedLine Citation:
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PMID: 19569710 Owner: NLM Status: PubMed-not-MEDLINE |
Abstract/OtherAbstract:
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As the global demand for low-cost renewable energy sources intensifies, interest in new routes for converting solar energy to electricity is rapidly increasing. Although photovoltaic cells have been commercially available for more than 50 years, only 0.1% of the total electricity generated in the United States comes directly from sunlight. The earliest commercial solar technology remains the basis for the most prevalent devices in current use, namely, highly-ordered crystalline, inorganic solar cells, commonly referred to as silicon cells. Another class of solar cells that has recently inspired significant academic and industrial excitement is the bulk heterojunction (BHJ) "plastic" solar cell. Research by a rapidly growing community of scientists across the globe is generating a steady stream of new insights into the fundamental physics, the materials design and synthesis, the film processing and morphology, and the device science and architecture of BHJ technology. Future progress in the fabrication of high-performance BHJ cells will depend on our ability to combine aspects of synthetic and physical chemistry, condensed matter physics, and materials science. In this Account, we use a combination of characterization tools to tie together recent advances in BHJ morphology characterization, device photophysics, and thin-film solution processing, illustrating how to identify the limiting factors in solar cell performance. We also highlight how new processing methods, which control both the BHJ phase separation and the internal order of the components, can be implemented to increase the power conversion efficiency (PCE). The failure of many innovative materials to achieve high performance in BHJ solar cell devices has been blamed on "poor morphology" without significant characterization of either the structure of the phase-separated morphology or the nature of the charge carrier recombination. We demonstrate how properly controlling the "nanomorphology", which is critically dependent on minute experimental details at every step, from synthesis to device construction, provides a clear path to >10% PCE BHJ cells, which can be fabricated at a fraction of the cost of conventional solar cells. |
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Authors:
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Jeffrey Peet; Alan J Heeger; Guillermo C Bazan |
Publication Detail:
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Type: Journal Article |
Journal Detail:
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Title: Accounts of chemical research Volume: 42 ISSN: 1520-4898 ISO Abbreviation: Acc. Chem. Res. Publication Date: 2009 Nov |
Date Detail:
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Created Date: 2009-11-17 Completed Date: 2009-11-17 Revised Date: - |
Medline Journal Info:
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Nlm Unique ID: 0157313 Medline TA: Acc Chem Res Country: United States |
Other Details:
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Languages: eng Pagination: 1700-8 Citation Subset: - |
Affiliation:
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Center for Polymers and Organic Solids, University of California at Santa Barbara, Santa Barbara, California 93106, USA. |
Export Citation:
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Descriptor/Qualifier:
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From MEDLINE®/PubMed®, a database of the U.S. National Library of Medicine
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