Investigation and Modelling of Single-Molecule Organic Transistors

F. Torricelli, E. Macchia, P. Romele, K. Manoli, C. Franco, Z. Kovács-Vajna, G. Palazzo, G. Scamarcio, L. Torsi
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Abstract

Biofunctionalized organic transistors have been recently proposed as a simple wide-field single molecule technology. The further development and engineering of this disruptive technology urgently requires the understanding and modelling of the device operation. Here we show a physical-based numerical model of single molecule organic transistors. The model accurately reproduces the measurements in the whole range of protein concentrations with a unique set of parameters. The model provides quantitative information on the bioelectronic device operation. It is an important tool for further development of transistor-based single molecule.
单分子有机晶体管的研究与建模
生物功能化有机晶体管最近被提出作为一种简单的宽场单分子技术。这种颠覆性技术的进一步发展和工程迫切需要对设备操作的理解和建模。在这里,我们展示了一个基于物理的单分子有机晶体管的数值模型。该模型用一组独特的参数精确地再现了整个蛋白质浓度范围内的测量结果。该模型提供了生物电子器件操作的定量信息。这是进一步开发基于晶体管的单分子材料的重要工具。
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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