Novel primary photoexcitations in \(\pi\)-conjugated donor-acceptor copolymers probed by transient magneto-photoinduced-absorption

The saga of the primary photoexcitations in \(\pi\)-conjugated polymers has been a source of extraordinary scientific curiosity that has lasted for more than three decades. From soliton excitations in trans-polyacetylene, to singlet and triplet excitons and polarons in other polymers, to charge tran...

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Veröffentlicht in:arXiv.org 2015-10
Hauptverfasser: Huynh, Uyen N V, Basel, Tek P, Dou, L, Aryanpour, Karan, Li, Gang, Mazumdar, Sumit, Ehrenfreund, Eitan, Yang, Yang, Vardeny, Z Valy
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Sprache:eng
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Zusammenfassung:The saga of the primary photoexcitations in \(\pi\)-conjugated polymers has been a source of extraordinary scientific curiosity that has lasted for more than three decades. From soliton excitations in trans-polyacetylene, to singlet and triplet excitons and polarons in other polymers, to charge transfer excitons in blends of polymers and fullerenes, the field has been rich with a variety of different photoexcitation species. Here we show the photogeneration of a novel primary intrachain photoexcitation species, namely the composite multi-exciton (CME) in \(\pi\)-conjugated donor-acceptor (DA)-copolymers used in organic photovoltaic (OPV) solar cells. We utilized the magnetic field response of the transient photoinduced absorption from sub-picosecond to millisecond to show in pristine DA-copolymer early photogeneration of the CME species that is composed of four coupled spin 1/2 particles, having unique optical and magnetic signatures. This species decomposes into two independent triplets in the microsecond time domain. Importantly in copolymer/fullerene blends the CME ionization generates photocarriers by a unique process that may enhance the photocurrent in OPV solar cells.
ISSN:2331-8422