Issue 5, 2013

Engineering polydopamine films with tailored behaviour for next-generation eumelanin-related hybrid devices

Abstract

Eumelanin-type biopolymers have attracted growing interest in the quest for soft bioinspired functional materials for application in organoelectronics. Recently, a metal-insulator-semiconductor device with a good quality interface was produced by spin coating of a commercial synthetic eumelanin-like material on a dry plasma-modified silicon surface. As a proof-of-concept step toward the design and implementation of next-generation eumelanin-inspired devices, we report herein an expedient chemical strategy to bestow n-type performance to polydopamine, a highly popular eumelanin-related biopolymer with intrinsic semiconductor behaviour, and to tune its electrical properties. The strategy relies on aerial co-oxidation of dopamine with suitable aromatic amines, e.g. 3-aminotyrosine or p-phenylenediamine, leading to good quality black polymeric films. Capacitance–voltage experiments on poly(dopamine/3-aminotyrosine) and poly(dopamine/p-phenylenediamine)-based metal insulator semiconductor devices on p-Si indicated a significant increase in flat band voltage with respect to polydopamine and previous synthetic eumelanin-based diodes. Variations of the flat band voltage under vacuum were observed for each device. These results point to polydopamine as a versatile eumelanin-type water-dependent semiconductor platform amenable to fine tuning of its electronic properties through incorporation of π-conjugating aromatic amines to tailor functionality.

Graphical abstract: Engineering polydopamine films with tailored behaviour for next-generation eumelanin-related hybrid devices

Supplementary files

Article information

Article type
Paper
Submitted
24 Oct 2012
Accepted
14 Nov 2012
First published
14 Nov 2012

J. Mater. Chem. C, 2013,1, 1018-1028

Engineering polydopamine films with tailored behaviour for next-generation eumelanin-related hybrid devices

M. Ambrico, P. F. Ambrico, A. Cardone, N. F. Della Vecchia, T. Ligonzo, S. R. Cicco, M. M. Talamo, A. Napolitano, V. Augelli, G. M. Farinola and M. d'Ischia, J. Mater. Chem. C, 2013, 1, 1018 DOI: 10.1039/C2TC00480A

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