Sustainable
Electronic Materials: Reversible Phototuning
of Conductance in a Noncovalent Assembly of MWCNT and Bioresource-Derived
Photochromic Molecule
Version 2 2017-01-03, 16:23Version 2 2017-01-03, 16:23
Version 1 2016-12-21, 12:18Version 1 2016-12-21, 12:18
journal contribution
posted on 2016-12-06, 00:00authored byKizhisseri
Devi Renuka, C. Lalitha Lekshmi, Kuruvilla Joseph, Sankarapillai Mahesh
Tuning the microstructure, conductance,
band gap of a single molecule
with an external stimuli such as light have vital importance in nanoscale
molecular electronics. Azobenzene systems are inimitable light responsive
molecules suitable for the development of optically modulated materials.
In this work we have demonstrated the development of an optically
active Multiwalled Carbon Nanotube (MWCNT)-hybrid material by the
noncovalent functionalization of azo based chromophore derived from
cardanol, a bioresource material. This photoresponsive noncovalent
hybrid shows trans–cis photoisomerization induced switching
of conductance. We report this as the first example in which the photochromic
assembly developed from a bioresource material exhibited tunable conductivity.
We expect that this novel photoswitchable hybrid with reversible conductance
may have potential applications in nanoscale molecular electronics,
solar cells, OLEDs, etc.