用于热敏电阻的单层 CVD 石墨烯非线性电子器件。

IF 2.9 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Saraswati Behera
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引用次数: 0

摘要

本文介绍了基于单层(SL)化学气相沉积(CVD)石墨烯的简单、经济、无源电子器件,这些器件在环境温度下显示出非线性和不对称的电流电压特性(CVC)。石墨烯与 Al2O3-Ti-Au 的接触产生了非线性电阻,从而实现了 CVC 的非线性。在转移到聚对苯二甲酸乙二醇酯(PET)上后,CVD 生长的 SL 石墨烯显示出 6200 cm2 V-1S-1 的迁移率。我们在所制造的器件中观察到了热电效应和热阻效应,例如在低压和高压(±200 mV - ±4V)以及温度(4 - 300 K)下,通过非对称和非线性 CVC 产生的与电压和温度有关的电子功率和电阻变化。基于石墨烯的热感应器件具有超薄、成本效益高、无毒/有机、灵活和高速等特点,可集成到未来的 CMOS 接口、可穿戴自供电电子设备中。已实现的非线性石墨烯集成电阻器具有很强的热阻性,可应用于热敏电阻。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nonlinear electronic devices on single-layer CVD graphene for thermistors.

In this article, we present simple, cost-effective, passive (non-gated) electronic devices based on single-layer (SL) chemical vapor deposited (CVD) graphene that show nonlinear and asymmetric current-voltage characteristics (CVCs) at ambient temperatures. Al2O3-Ti-Au contacts to graphene results in a nonlinear resistance to achieve nonlinearity in the CVC. Upon transfer to polyethylene terephthalate, the CVD-grown SL graphene shows mobility of 6200 cm2V-1S-1. We have observed both thermoelectric effect and thermoresistive sensing in the fabricated devices such as voltage and temperature concerning change in electronic power and resistance through asymmetric and nonlinear CVC. The device is stable both at low and high voltages (±200 mV to ±4 V) and temperatures (4 K - 300 K). Graphene-based thermosensing devices can be ultra-thin, cost-effective, non-toxic/organic, flexible, and high-speed for integration into future complementary metal-oxide semiconductor (CMOS) interface, and wearable self-power electronics. A strong negative temeperature coefficent of resistance is demonstrated in the realized nonlinear graphene-integrated resistors for its application in NTC thermistors.

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来源期刊
Nanotechnology
Nanotechnology 工程技术-材料科学:综合
CiteScore
7.10
自引率
5.70%
发文量
820
审稿时长
2.5 months
期刊介绍: The journal aims to publish papers at the forefront of nanoscale science and technology and especially those of an interdisciplinary nature. Here, nanotechnology is taken to include the ability to individually address, control, and modify structures, materials and devices with nanometre precision, and the synthesis of such structures into systems of micro- and macroscopic dimensions such as MEMS based devices. It encompasses the understanding of the fundamental physics, chemistry, biology and technology of nanometre-scale objects and how such objects can be used in the areas of computation, sensors, nanostructured materials and nano-biotechnology.
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