Super-resolution photothermal patterning in conductive polymers and nanowire patterning

Organic and Hybrid Light Emitting Materials and Devices XXV Pub Date : 2021-08-02 DOI:10.1117/12.2595890

A. Moulé, Ian E. Jacobs, Z. I. Bedolla-Valdez, Goktug Gonel, Camila Cendra, Jun Li, Brandon T. Rotondo, David J. Bilsky, Ryan Lewis, Rui Xiao, Alejandra N. Ayala Oviedo, Alice S. Fergerson, Zekun Chen, Dong Yu, A. Salleo

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Abstract

The largest need in organic electronic devices is a universal method to produce micro- to nano-scale features for devices from semiconducting polymers cheaply, and at scale. We recently developed a solution method to optically pattern conjugated polymers with resolution that exceeds the linear Abbe diffraction limit. We examine the relationship between optical write intensity, write speed, and write wavelength on the resulting pattern fidelity. Finite element modeling reveals that nearly all patterning occurs as a result of local heating and superlinear resolution is a result of a highly non-linear dissolution rate for the polymer as a function of temperature. This result is general to any conjugated polymer. We used this new technique to fabricate P3HT/F4TCNQ nanowires We also demonstrate that a P3HT nanowires can be doped and de-doped from solution without changing the dimension of the wire.

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导电聚合物的超分辨率光热图像化和纳米线图像化

有机电子器件的最大需求是一种通用的方法，以低成本和大规模地用半导体聚合物生产微到纳米级的器件。我们最近开发了一种光学模式共轭聚合物的解决方法，其分辨率超过线性阿贝衍射极限。我们研究了光写入强度、写入速度和写入波长对所得到的图形保真度的关系。有限元模型表明，几乎所有的图案都是局部加热的结果，而超线性分辨率是聚合物溶解速率作为温度函数的高度非线性的结果。这一结果适用于任何共轭聚合物。我们使用这种新技术制备了P3HT/F4TCNQ纳米线，我们还证明了P3HT纳米线可以在不改变线的尺寸的情况下从溶液中掺杂和脱掺杂。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Organic and Hybrid Light Emitting Materials and Devices XXV

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