Materials and devices for advanced transistors and olfactory sensors

用于先进晶体管和嗅觉传感器的材料和器件

• 批准号: 261261-2013
• 负责人: Buchanan, Douglas
• 金额: $ 2.11万
• 依托单位: University of Manitoba
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=637590
• 关键词: Materials; devices; advanced; transistors; olfactory

The research to be performed in this program focuses on a wide range of micro- and nano-electronic thin film materials and devices. Applications for these materials and devices include "standard" silicon based devices, olfactory sensors, ultrasonic transducers and microfluidic devices. The long range objective of my research program is to advance the state-of-the-art of micro- and nano-electrics devices through the application of materials based research to novel devices and applications. In the present proposal there are two tasks or projects within this program that are being undertaken. Current silicon devices are getting smaller and tolerances are now at the atomic level. This work expands the understanding of the physical and electronic properties of materials and devices what are so important to continued increase of device performance. The latest estimates suggest dimensions will scale to 11nm by 2020. High performance devices will require the introduction of high mobility semiconductors and the scaling of insulator thicknesses below 0.7nm. This research directly addresses the future scaling of transistors in the semiconductor industry. Training in this area will make students very desirable for academic or industrial (semiconductor-related) industries. Research is also undertaken on commercially fabricated silicon-based devices incorporating polymers to produce "programmable" olfactory sensors; an electronic nose. This work is applicable to many different industries including food and beverage (including spirits), agriculture (testing of spoilage in silos), and the automobile industry (emissions). This sensor is fabricated using a standard chip technology making it relatively inexpensive. Very large, "mega-pixel" systems can be fabricated that contain many different polymers making the device "programmable". This array system is extremely flexible and can be applied to any industry where in the sensing of volatile odors is required. Students involved in these studies will be uniquely trained in a multitude of cross-disciplinary areas making them highly desirable in academia or industry.

该项目的研究重点是广泛的微纳米电子薄膜材料和器件。这些材料和设备的应用包括“标准”硅基设备、嗅觉传感器、超声波换能器和微流体设备。我的研究计划的长期目标是通过将基于材料的研究应用于新颖的设备和应用来推进最先进的微电子和纳米电子设备。在本提案中，该计划内正在开展两项任务或项目。当前的硅器件越来越小，公差现已达到原子级别。这项工作扩展了对材料和设备的物理和电子特性的理解，这对于持续提高设备性能非常重要。最新估计表明，到 2020 年，尺寸将扩大到 11 纳米。高性能器件将需要引入高迁移率半导体，并将绝缘体厚度缩小到 0.7 纳米以下。这项研究直接解决了半导体行业晶体管未来的扩展问题。该领域的培训将使学生非常适合学术或工业（半导体相关）行业。还对商业制造的硅基设备进行了研究，该设备包含聚合物以生产“可编程”嗅觉传感器；电子鼻。这项工作适用于许多不同的行业，包括食品和饮料（包括烈酒）、农业（筒仓中的腐败测试）和汽车工业（排放）。该传感器采用标准芯片技术制造，使其相对便宜。可以制造非常大的“百万像素”系统，其中包含许多不同的聚合物，使设备“可编程”。该阵列系统非常灵活，可应用于任何需要检测挥发性气味的行业。参与这些研究的学生将在多个跨学科领域接受独特的培训，使他们在学术界或工业界非常受欢迎。