Laser-induced graphene supercapacitors on flex substrates for package-integrated power supply

2023 Fourth International Symposium on 3D Power Electronics Integration and Manufacturing (3D-PEIM) Pub Date : 2023-02-01 DOI:10.1109/3D-PEIM55914.2023.10052332

Reshmi Banerjee, A. Chowdhury, Pavar Sai Kumar, Chunlei Wang, S. Goel, P. Raj

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引用次数: 2

Abstract

Integrated power sources have a critical role in the operation of miniaturized, lightweight, wearable medical and IoT devices. Such power sources should be ideally grown directly on the package substrates for low-impedance power delivery and assembled in planar architectures while also achieving higher power densities. This paper shows laser-induced graphene supercapacitors on flexible packages to address that critical need. With the proper selection of laser wavelength and power, polyimide can be selectively transformed into porous graphene to form high surface area electrodes. These graphene layers are integrated with copper tape to a stainless-steel substrate to form planar supercapacitor layers. Initial testing was performed with liquid electrolytes. Capacitance densities of 1.2 mF/cm2, comparable to current porous graphene capacitors but with a simpler process, was thus achieved. This unique nanomanufacturing paradigm can broadly benefit all future power module integration strategies.

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用于封装集成电源的柔性基板激光诱导石墨烯超级电容器

集成电源在小型化、轻量化、可穿戴医疗和物联网设备的运行中起着至关重要的作用。理想情况下，这种电源应该直接生长在封装基板上，以实现低阻抗的功率传输，并在平面架构中组装，同时还可以实现更高的功率密度。本文展示了柔性封装上的激光诱导石墨烯超级电容器，以解决这一关键需求。通过选择合适的激光波长和功率，聚酰亚胺可以选择性地转化为多孔石墨烯，形成高表面积电极。这些石墨烯层与铜带集成到不锈钢衬底上，形成平面超级电容器层。最初的测试是用液体电解质进行的。电容密度为1.2 mF/cm2，与目前的多孔石墨烯电容器相当，但工艺更简单。这种独特的纳米制造模式可以广泛地受益于所有未来的电源模块集成策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2023 Fourth International Symposium on 3D Power Electronics Integration and Manufacturing (3D-PEIM)

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