Efficient Electron Mobility in an All-Acceptor Napthalenediimide-Bithiazole Polymer Semiconductor with Large Backbone Torsion

Ly, Jack T.; Burnett, Edmund K.; Thomas, Simil; Aljarb, Areej; Liu, Yao; Park, Soohyung; Rosa, Stephen; Yi, Yeonjin; Lee, Hyunbok; Emrick, Todd; Russell, Thomas P.; Bredas, Jean-Luc; Briseno, Alejandro L.

Type

Article

Authors

Ly, Jack T.
Burnett, Edmund K.
Thomas, Simil
Aljarb, Areej
Liu, Yao
Park, Soohyung
Rosa, Stephen
Yi, Yeonjin
Lee, Hyunbok
Emrick, Todd
Russell, Thomas P.
Bredas, Jean-Luc

Briseno, Alejandro L.

KAUST Department

KAUST Solar Center (KSC)
Laboratory for Computational and Theoretical Chemistry of Advanced Materials
Material Science and Engineering Program
Physical Science and Engineering (PSE) Division

Date

2018-10-31

Online Publication Date

2018-10-31

Print Publication Date

2018-11-21

Permanent link to this record

http://hdl.handle.net/10754/630600

Metadata

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Abstract

An all-acceptor napthalenediimide-bithiazole-based co-polymer, P(NDI2OD-BiTz), was synthesized and characterized for application in thin-film transistors. Density functional theory calculations point to an optimal perpendicular dihedral angle of 90° between acceptor units along isolated polymer chains; yet optimized transistors yield electron mobility of 0.11 cm2/(V s) with the use of a zwitterionic naphthalene diimide interlayer. Grazing incidence X-ray diffraction measurements of annealed films reveal that P(NDI2OD-BiTz) adopts a highly ordered edge-on orientation, exactly opposite to similar bithiophene analogs. This report highlights an NDI and thiazole all-acceptor polymer and demonstrates high electron mobility despite its nonplanar backbone conformation.

Citation

Ly JT, Burnett EK, Thomas S, Aljarb A, Liu Y, et al. (2018) Efficient Electron Mobility in an All-Acceptor Napthalenediimide-Bithiazole Polymer Semiconductor with Large Backbone Torsion. ACS Applied Materials & Interfaces 10: 40070–40077. Available: http://dx.doi.org/10.1021/acsami.8b11234.

Sponsors

We acknowledge the Office of Naval Research (Awards N00014-16-1-2612 and N000147-14-1-0053 at Penn State and Award N00014-17-1-2208 at Georgia Tech). Y.L. and T.P.R. were supported by the Office of Naval Research, Materials Division, under contract N00014-17-1-2244. This work is based upon research conducted at the Cornell High Energy Synchrotron Source (CHESS), which is supported by the National Science Foundation under award DMR1332208. We would like to also thank Megan Matta and Sarah Sheffield, graduate students of Penn State, for conducting TGA and DSC measurements provided in the SI.