Electronic and Optically controlled Bi-functional Transistor based on Bio-Nano Hybrid Complex

TL;DR

This paper presents a novel bio-nano hybrid transistor combining purple membrane and carbon nanotubes, demonstrating optically and electronically controlled bi-functionality with significant switching and photoconductivity.

Contribution

The work introduces a dual-controlled bio-electronic FET based on a bio-nano hybrid, showcasing combined optical and electronic regulation of its semiconducting properties.

Findings

Conductivity of 19 microS/m in the hybrid film.

Photoconductivity of 13.15 microS/m in the device.

On/Off ratio of 8.5 in the transistor.

Abstract

We report optically as well as electronically controlled, bio-electronic field-effect transistor (FET) based on the hybrid film of a photo-active purple membrane and electronically conducting single-walled carbon nanotubes (SWNTs). Two dimensional (2D) crystal of bacteriorhodopsin forms the photoactive center of the bio-nano complex, whereas one dimensional (1D) pure SWNTs provides the required electronic support. The hybrid structure shows a conductivity of 19 microS/m and semiconducting characteristics due to preferential binding with selective diameters of semiconducting SWNTs only. The bio-electronic transistor fabricated using direct laser lithography shows photoconductivity of 13.15 microS/m and well-controlled optical and electronic gating with a significant On/Off switch ratio of 8.5. The device demonstrates well-synchronized electronic and optical gating wherein, n-type FET shows complementary p-type characteristics due to optically controlled proton-pumping by bacteriorhodopsin. Fabricated bio-electronic transistor displays both electronically and optically well-controlled, bi-functionality.