Issue 11, 2014

High-speed scanning thermal lithography for nanostructuring of electronic devices

Abstract

We report a detailed analysis on the use of simultaneous substrate heating in conjunction with scanning thermal lithography (SThL) to dramatically increase the patterning speed of conventional SThL systems. The investigation consists of finite element simulations as well as practical assessments of the speed at which different organic precursors are thermally converted to produce standalone electrically active and passive nanostructures. As a proof of concept the high-speed SThL method was used to pattern semiconducting pentacene nanoribbons, which were subsequently incorporated into functioning transistors. Simultaneous substrate heating was found to allow patterning of functional devices at writing speeds >19 times higher than transistors produced at identical speeds but with the substrate maintained at room temperature. These fast written transistors exhibit 100× higher hole mobility with high on/off current ratio and negligible operating hysteresis. The generality of the proposed high-speed SThL method was further demonstrated with the rapid patterning of conductive nanostructured metal electrodes with excellent spatial resolution employing an appropriate polymer precursor as the chemical resist. It is proposed that these advances further support the case for using SThL systems as rapid prototypers for low micron and nanoscale structures for both direct patterning of precursors and indirect patterning of metals and other materials using suitable chemical resist.

Graphical abstract: High-speed scanning thermal lithography for nanostructuring of electronic devices

Article information

Article type
Paper
Submitted
13 Jan 2014
Accepted
04 Apr 2014
First published
17 Apr 2014

Nanoscale, 2014,6, 5813-5819

Author version available

High-speed scanning thermal lithography for nanostructuring of electronic devices

J. E. Shaw, P. N. Stavrinou and T. D. Anthopoulos, Nanoscale, 2014, 6, 5813 DOI: 10.1039/C4NR00209A

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