用于室内二氧化碳气体传感的 BGBC OTFT 实验特性分析

Mohamad Nasyran Zailan, Khadijah Ismail, Murniati Syaripuddin, Mohd Salman Mohd Sabri
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引用次数: 0

摘要

由于过量向环境释放有害气体,导致全球范围内出现温室效应现象,全球变暖已成为一个令人担忧的问题。根据全球污染机构提供的数据,向大气释放温室气体是污染和气候变暖导致大气温度上升的主要原因。释放到环境中的温室气体(GHGs)含量令人担忧,据报道,与其他气体相比,二氧化碳(CO2)的浓度最高。许多研究都在开发和评估含有无机和有机半导体材料的有害气体传感器的性能。有机半导体(OSC)是一种环保材料,技术成本相对较低,而且由多种材料组成,具有良好的载流子迁移率。因此,本研究开发了用于气体传感器的有机薄膜晶体管(OTFT)。由于全球变暖问题日趋严重,与传统无机材料的复杂工艺相比,通过范德华键结合在一起的有机分子很容易通过低温沉积和溶液处理进行加工,因此这种解决方案是一种可持续的环保解决方案。此外,由于能承受高湿度条件,所开发的传感器一般都很坚固,而且可以在柔性基底上制造。在这项工作中,确定了基本 OTFT 结构的合适材料,即电极、电介质和衬底。研究范围主要集中在底栅 OTFT 结构的开发上,其中采用了 p 型活性材料,即三异丙基硅烷基五苯(TIPS Pentacene)、铝(Al)作为漏极和源极,PEDOT:PSS 作为栅极,聚乙烯醇 (PVA) 作为栅极电介质。通过丝网印刷技术制作的底栅底部接触 (BGBC) 配置材料进行了二氧化碳检测实验测试。最初检测到的二氧化碳浓度为 1618 ppm,接触电阻为 15 kΩ,在 10 毫升/分钟的流速下,所开发的配置的灵敏度达到 2.069 Ω/ppm。总之,所研究的 BGBC OTFT 已证明适用于二氧化碳气体传感,可用于可持续的环境状况监测,从而为地球上的生物提供更安全的环境。根据所提出的尺寸,未来有可能采用光刻等更先进的技术来制造这项工作。
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Experimental Characterisation of BGBC OTFT for Indoor CO2 Gas Sensing
Global warming is a concern nowadays due to excessive release of harmful gasses to the environment, leading to greenhouse effect phenomena worldwide. Based on the data provided by global pollution agencies, the release of greenhouse gasses to the atmosphere is the main cause of pollution and the increase in atmospheric temperature due to warming. Greenhouse gasses (GHGs) contents released to the environment is worrying, with carbon dioxide (CO2) is reported at the highest concentration compared to other gasses. There are many studies conducted to develop and evaluate the performance of harmful gas sensors incorporating inorganic and organic semiconductive materials. Organic semiconductors (OSCs) are environmentally friendly materials, relatively cheaper technology, and comprised of a wide range of materials with good carrier mobility. Therefore, in this work, Organic Thin Film Transistor (OTFT) is developed for gas sensor application. As global warming is becoming more serious, this solution is instead a sustainable solution to the environment, as organic molecules which are held together via Van der Waals bond are easily processed via low-temperature deposition and solution processing as compared to more complicated processes involved in conventional inorganic counterpart. In addition, the developed sensor is generally robust due to the ability to withstand high humidity conditions and can be fabricated on flexible substrates. In this work, suitable materials are identified in basic OTFT construction, which are the electrodes, dielectric and substrate. The scope is mainly focusing on the development of bottom gate OTFT construction, incorporating p-type active material which are Trisisopropylsilylethynyl Pentacene (TIPS Pentacene), Aluminium (Al) as drain and source electrodes, PEDOT: PSS as gate electrode and Polyvinyl alcohol (PVA) as gate dielectric. The materials in bottom gate bottom contact (BGBC) configuration, fabricated via screen printing technique is experimentally tested towards CO2 detection. CO2 is initially detected at 1618 ppm with contact resistance of 15 kΩ, and at 10 ml/minute flow rate, the developed configuration is demonstrated able to achieve sensitivity of 2.069 Ω/ppm. In conclusion, the studied BGBC OTFT has demonstrated suitability and applicability in CO2 gas sensing for sustainable environmental condition monitoring, that could lead to safer environment for the living things on earth. With the proposed dimensions, in the future it is possible to proceed with this work to be fabricated by using more advanced techniques such as photolithography and many others.
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