6533b86ffe1ef96bd12cdb28

RESEARCH PRODUCT

Anthracene Based Conjugated Polymers: Correlation between π−π-Stacking Ability, Photophysical Properties, Charge Carrier Mobility, and Photovoltaic Performance

Florian KühnlenzRupali JadhavRupali JadhavGetachew AdamNiyazi Serdar SariciftciStefan TürkDaniel A. M. EgbeDaniel A. M. EgbeVera CimrovaHarald HoppeSilke RathgeberAndreas WildGünther KnörAlmantas PivrikasEckhard Birckner

subject

chemistry.chemical_classificationAnthraceneMaterials sciencePolymers and PlasticsOpen-circuit voltageOrganic ChemistryStackingPolymerConjugated systemlaw.inventionInorganic Chemistrychemistry.chemical_compoundCrystallographychemistrylawSolar cellPolymer chemistryMaterials ChemistrySide chainAlkoxy group

description

This article reports on the synthesis, characterization and properties of a series of anthracene−containing poly(p-phenylene-ethynylene)-alt-poly(p-phenylene-vinylene)s (PPE−PPV) copolymers with general constitutional unit (Ph−C≡C−Anthr−C≡C−Ph−CH═CH−Ph−CH═CH−)n denoted AnE-PV. Solely linear (AnE-PVaa, -ad, -ae) and solely branched (AnE-PVbb) as well as mixed linear and branched (AnE-PVab, -ac, -ba, -cc) alkoxy side chains were grafted to the backbone in order to tune the π−π-stacking ability of the materials. It has been possible to establish a correlation between π−π-stacking ability, absorptive behavior, charge carrier mobility, solar cell active layer nanoscale morphology and resulting photovoltaic performance. Solar cells energy conversion efficiencies between 0.34% and 3.14% were achieved. The best performance was achieved from AnE-PVab showing both stacking ability and highest π−π-stacking distance of 0.386 nm as compared to 0.380 nm for the others. Poorer performance resulted from polymers with no ...

yearjournalcountryeditionlanguage
2010-01-04Macromolecules
https://doi.org/10.1021/ma902273s