Quantitative Determination of Charge Transport Interface at Vertically Phase Separated Soluble Acene/Polymer Blends

Abstract

Interfacial structure is critical for optimizing the electrical properties of organic field-effect transistors. In this study, the interfacial structures of 6,13-bis(triisopropylsilylethynyl)pentacene (TIPS-pentacene)/polymer blends are nondestructively determined by the complementary neutron and X-ray reflectivity. The TIPS-pentacene/deuterated poly(methylmethacrylate) (d-PMMA) blends exhibit a vertically phase-separated structure with a molecularly sharp interface (interfacial roughness approximate to 5 angstrom), whereas the TIPS-pentacene/d-polystyrene (d-PS) blend intermix near the interface. Ultrahigh molecular weight d-PMMA leads to the formation of surface-segregated hexagonal spherulites of TIPS-pentacene owing to the thermodynamic factors (e.g., surface/interface energy, polarity, and viscosity) of the blending materials. The well-developed hexagonal spherulites of TIPS-pentacene on molecularly sharp d-PMMA interface result in higher field-effect mobility as compared to the dendritic crystals from d-PS blends because of the higher perfectness, coverage, and interfacial roughness of the TIPS-pentacene crystals. The approach used in this study facilitates the understanding of the charge transport mechanism at the phase-separated interfaces in soluble acene/polymer blends.