Engineering thermally and electrically conductive nanomaterial-polymer composites for thermal sensing applications**

设计用于热传感应用的导热和导电纳米材料-聚合物复合材料**

• 批准号: 521262-2018
• 负责人: Elias, Anastasia
• 金额: $ 9.36万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Strategic Projects - Group
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=650062
• 关键词: Engineering; thermally; electrically; conductive; nanomaterial

In pharmaceutical, manufacturing, energy, and other industries, accurate knowledge of both temperature and thermal properties of materials is of critical importance. In some cases, these values and properties must be characterized during the production process. Some accurate systems for making thermal measurements are commercially available; one key part of these systems is a sensing material that has temperature-dependent properties (such as the electrical resistance of a metal, which changes with temperature). The applicability and availability of these systems is limited by the fact their cost remains high due to the difficulty in manufacturing reliable devices using conventional materials and processes. In addition, these devices can be bulky and brittle. ** The purpose of this work is to engineer materials that can be used to rapidly and inexpensively manufacture reliable thermal sensing devices on a variety of different types of surfaces. In this project, the University of Alberta will partner with C-Therm Technologies Ltd, a Canadian company that produces and distributes cutting-edge thermal analysis equipment to develop new, printable materials for thermal sensing applications based on polymer-nanomaterial composites. This work will take advantage of the unique thermal and electrical properties that can be achieved through engineering of composite materials. These composite materials can be designed to undergo very large and reversible changes in electrical properties (e.g. resistance and/or capacitance) as a function of temperature, allowing them to form the active material of sensing devices. ** This research will focus on two main aims. (AIM 1) Develop printable temperature-responsive materials that undergo a change in resistance as a function of temperature, and that can be patterned to form arrays of sensors for real-time mapping of thermal properties (including effusivity and heat capacity). (AIM 2) Utilize the unique properties of nanomaterials to engineer composites that undergo a change in capacitance in response to temperature. Outcomes will include both an in-depth understanding of material properties and new devices for industry.************

在制药、制造、能源和其他行业中，准确了解材料的温度和热特性至关重要。在某些情况下，这些值和属性必须在生产过程中进行表征。一些用于进行热测量的精确系统是商业上可获得的;这些系统的一个关键部分是具有温度依赖特性的传感材料（例如金属的电阻，其随温度变化）。这些系统的适用性和可用性受到以下事实的限制：由于难以使用常规材料和工艺制造可靠的装置，因此它们的成本仍然很高。此外，这些装置可能体积庞大且易碎。** 这项工作的目的是设计可用于在各种不同类型的表面上快速，廉价地制造可靠的热传感设备的材料。 在这个项目中，阿尔伯塔大学将与C-Therm Technologies Ltd合作，C-Therm Technologies Ltd是一家加拿大公司，生产和分销尖端的热分析设备，以开发基于聚合物纳米材料复合材料的热传感应用的新的可打印材料。这项工作将利用独特的热和电性能，可以通过复合材料的工程实现。这些复合材料可以被设计为随着温度的变化而经历电特性（例如电阻和/或电容）的非常大且可逆的变化，从而允许它们形成感测装置的活性材料。 ** 本研究将侧重于两个主要目标。(AIM 1）开发可印刷的温度响应材料，其电阻随温度变化，并且可以被图案化以形成传感器阵列，用于实时映射热特性（包括扩散率和热容）。(AIM 2）利用纳米材料的独特性质来设计复合材料，使其电容随温度变化。 成果将包括对材料特性的深入了解和工业新设备。*