Enhancing doping efficiency by improving host-dopant miscibility for fullerene-based n-type thermoelectrics

Journal article
Materials science
Polymers
Author

Li Qiu, Jian Liu, Riccardo Alessandri, Xinkai Qiu, Marten Koopmans, Remco W. A. Havenith, Siewert J. Marrink, Ryan C. Chiechi, L. Jan Anton Koster and Jan C. Hummelen

Doi

Citation (APA 7)

Qiu, L., Liu, J., Alessandri, R., Qiu, X., Koopmans, M., Havenith, R. W., … & Hummelen, J. C. (2017). Enhancing doping efficiency by improving host-dopant miscibility for fullerene-based n-type thermoelectrics. Journal of materials chemistry A, 5(40), 21234-21241.

Abstract

This paper describes a promising n-type doping system with high performance for thermoelectric applications. By introducing the polar triethylene glycol (TEG) side chain onto both fullerene host (PTEG-1) and dopant (TEG-DMBI) materials, the TEG-DMBI doped PTEG-1 films obtained through solution processing provide a better miscibility compared with films doped with commercially available N-DMBI (bearing a dimethylamino group instead of TEG), as determined by phase imaging AFM (atomic force microscopy) measurements and coarse-grain molecular dynamics simulations, leading to high doping efficiency up to 18% at 20 mol% doping concentration and thus high carrier density and mobility, which are critical to the electrical conductivity. Therefore a record power factor of 19.1 μW m−1 K−2 is obtained with an electrical conductivity of 1.81 S cm−1, one of the highest values reported for solution processable fullerene derivatives as n-type organic materials for thermoelectric applications to date.