Energy-efficiency and thermal management in nanoscale devices

A. Liao, Z. Ong, A. Serov, F. Xiong, E. Pop
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引用次数: 2

Abstract

Power consumption and thermal management are significant challenges in electronics, from mobile devices to data centers. A fundamental examination of such aspects could lead to orders of magnitude improvements in energy efficiency. We present recent highlights from our work examining dissipation in nanoscale devices, at contacts, interfaces, and in novel materials. Advances include the use of high-thermal conductivity materials (graphene), low-power data storage (based on phase change rather than charge), and thermoelectric effects for highly localized cooling. Results suggest much room to improve power dissipation in nanoscale electronics, towards fundamental limits, through the co-design of geometry and materials.
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纳米级器件的能源效率和热管理
从移动设备到数据中心,功耗和热管理是电子领域的重大挑战。对这些方面进行根本性的检查,可以使能源效率得到数量级的提高。我们介绍了我们最近在纳米器件、接触、界面和新材料中研究耗散的重点工作。进步包括使用高导热材料(石墨烯),低功耗数据存储(基于相变而不是电荷),以及用于高度局部冷却的热电效应。结果表明,通过几何和材料的共同设计,纳米级电子学的功耗有很大的提高空间,可以达到基本的极限。
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