Review of Si-Based Thin Films and Materials for Thermoelectric Energy Harvesting and Their Integration into Electronic Devices for Energy Management Systems

C. Ascencio-Hurtado, R. C. Ambrosio Lázaro, J. Estrada-López, A. Torres Jacome
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Abstract

Energy harvesters are autonomous systems capable of capturing, processing, storing, and utilizing small amounts of free energy from the surrounding environment. Such energy harvesters typically involve three fundamental stages: a micro-generator or energy transducer, a voltage booster or power converter, and an energy storage component. In the case of harvesting mechanical vibrations from the environment, piezoelectric materials have been used as a transducer. For instance, PZT (lead zirconate titanate) is a widely used piezoelectric ceramic due to its high electromechanical coupling factor. However, the integration of PZT into silicon poses certain limitations, not only in the harvesting stage but also in embedding a power management electronics circuit. On the other hand, in thermoelectric (TE) energy harvesting, a recent approach involves using abundant, eco-friendly, and low-cost materials that are compatible with CMOS technology, such as silicon-based compound nanostructures for TE thin film devices. Thus, this review aims to present the current advancements in the fabrication and integration of Si-based thin-film devices for TE energy harvesting applications. Moreover, this paper also highlights some recent developments in electronic architectures that aim to enhance the overall efficiency of the complete energy harvesting system.
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热电能量收集用硅基薄膜和材料及其在能量管理系统电子器件中的集成研究进展
能量收集器是一种能够捕获、处理、储存和利用来自周围环境的少量自由能量的自主系统。这种能量收集器通常包括三个基本阶段:微型发电机或能量转换器,电压增强器或功率转换器,以及能量存储组件。在从环境中收集机械振动的情况下,压电材料被用作换能器。例如,PZT(锆钛酸铅)由于其高机电耦合系数而成为一种应用广泛的压电陶瓷。然而,PZT集成到硅中存在一定的局限性,不仅在收获阶段,而且在嵌入电源管理电子电路方面也存在一定的局限性。另一方面,在热电(TE)能量收集方面,最近的一种方法涉及使用与CMOS技术兼容的丰富,环保和低成本的材料,例如用于TE薄膜器件的硅基化合物纳米结构。因此,本综述旨在介绍用于TE能量收集应用的硅基薄膜器件的制造和集成的最新进展。此外,本文还强调了电子架构的一些最新发展,旨在提高整个能量收集系统的整体效率。
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