Optimized Synthesis of Thermally Stable Axially Modified Pyrazine-Acene Nanoribbon With Gelation Properties

Authors

Sae Hui Lee, University of Nevada, Las Vegas
Marco S. Valverde Paredes, University of Nevada, Las Vegas
Taylor J. Rappenecker, University of Nevada, Las Vegas
Kathleen A. Robins, University of Nevada, Las VegasFollow
Dong-Chan Lee, University of Nevada, Las VegasFollow

Document Type

Article

Publication Date

1-1-2020

Publication Title

New Journal of Chemistry

Volume

44

First page number:

3604

Last page number:

3611

Abstract

In this paper, we explored comprehensive synthetic approaches to axially substituted N-heteroacene based nanoribbon with 11 linearly annulated rings. Although synthetically tedious, we found that a stepwise cyclization between α-diketone and o-aromatic diamine to grow nanoribbon is more efficient than simultaneous dicylization in one step using 3,6-disubstituted-1,2,4,5-tetraaminobenzene. In addition, for the axial modification, pre-modification of a building block was superior to post-modification of preformed nanoribbon. The nanoribbon was characterized with UV-Vis spectroscopy, CV, DSC, and TGA. The nanoribbon showed a relatively stabilized ELUMO of −3.74 eV due to the electron-deficient nature of the core and reduced Egap of 1.55 eV as a result of intramolecular charge transfer between the core and axial thiophene. The electronic properties were also investigated with theoretical calculations at B3LYP/6-31G* level of theory/basis set. Particular attention was paid to the distribution of frontier molecular orbitals as these correlated with the measured electronic properties. The title nanoribbon exhibited remarkable thermal stability with a 424 °C decomposition temperature at 5% weight loss. The axially substituted nanoribbon showed excellent one-dimensional fibrillation properties via organogelation. The nanoribbon gelled hydrocarbon solvents and select halogenated solvents with the lowest critical gelation concentration of 1.2 mM in hexadecane. FE-SEM confirmed the existence of endless flexible one-dimensional fibers with a thickness of ca. 200 nm. Despite the large π-core, the axial functionalization imparted not only processability but also self-assembly ability while maintaining excellent thermal stability. These properties would be useful in future optoelectronic applications.

Disciplines

Chemistry

Language

English

Repository Citation

Lee, S. H., Valverde Paredes, M. S., Rappenecker, T. J., Robins, K. A., Lee, D. (2020). Optimized Synthesis of Thermally Stable Axially Modified Pyrazine-Acene Nanoribbon With Gelation Properties. New Journal of Chemistry, 44 3604-3611.
http://dx.doi.org/10.1039/c9nj06303j