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Quantifying the Energy Barriers and Elucidating the Charge Transport Mechanisms across Interspherulite Boundaries in Solution‐Processed Organic Semiconductor Thin Films
Author(s) -
Hailey Anna K.,
Wang SzuYing,
Chen Yuanzhen,
Payne Marcia M.,
Anthony John E.,
Podzorov Vitaly,
Loo YuehLin
Publication year - 2015
Publication title -
advanced functional materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 6.069
H-Index - 322
eISSN - 1616-3028
pISSN - 1616-301X
DOI - 10.1002/adfm.201501666
Subject(s) - grain boundary , materials science , spherulite (polymer physics) , crystallite , semiconductor , organic semiconductor , charge carrier , polymer , thin film , charge (physics) , optoelectronics , chemical physics , condensed matter physics , nanotechnology , composite material , chemistry , microstructure , physics , quantum mechanics , metallurgy
Grain boundaries act as bottlenecks to charge transport in devices comprising polycrystalline organic active layers. To improve device performance, the nature and resulting impact of these boundaries must be better understood. The densities and energy levels of shallow traps within and across triethylsilylethynyl anthradithiophene (TES ADT) spherulites are quantified. The trap density is 7 × 10 10 cm −2 in devices whose channels reside within a single spherulite and up to 3 × 10 11 cm −2 for devices whose channels span a spherulite boundary. The activation energy for charge transport, E A , increases from 34 meV within a spherulite to 50–66 meV across a boundary, depending on the angle of molecular mismatch. Despite being molecular in nature, these E A ’s are more akin to those found for charge transport in polymer semiconductors. Presumably, trapped TES ADT at the boundary can electrically connect neighboring spherulites, similar to polymer chains connecting crystallites in polymer semiconductor thin films.