Enabling Reconfigurable All-Liquid Microcircuits via Laplace Barriers to Control Liquid Metal

2019 IEEE MTT-S International Microwave Symposium (IMS) Pub Date : 2019-06-01 DOI:10.1109/mwsym.2019.8700919

A. Watson, Kareem S. Elassy, T. Leary, M. A. Rahman, A. Ohta, W. Shiroma, C. Tabor

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引用次数: 4

Abstract

Liquid metals such as gallium alloys have a unique potential to enable fully reconfigurable RF electronics. One of the major concerns for liquid-metal electronics is their interaction with solid-metal contacts, which results in unwanted changes to electrical performance and delamination of solid-metal contacts due to atomic diffusion of gallium at the liquid/solid interface. In this paper, we present a solution to this problem through way of liquid-metal/liquid-metal RF connections by implementing La-place barriers, which control fluid flow and position via pressure-sensitive thresholds to facilitate physical movement of the fluids within the channels. We demonstrate RF switching within the channel systems by fabricating, testing, and modeling a reconfigurable RF microstrip transmission line with integrated Laplace barriers which operates between 0.5–5 GHz. This approach opens the potential for future all-liquid reconfigurable RF electronic circuits where physical connections between solid and liquid metals are minimized or possibly eliminated altogether.

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通过拉普拉斯势垒实现可重构全液体微电路以控制液态金属

液态金属如镓合金具有独特的潜力，可以实现完全可重构的射频电子器件。液态金属电子学的主要问题之一是它们与固体金属触点的相互作用，由于镓在液/固界面的原子扩散，这会导致电性能的不必要变化和固体金属触点的分层。在本文中，我们提出了一种解决方案，通过实现La-place屏障，通过压力敏感阈值控制流体的流动和位置，以促进流体在通道内的物理运动，通过液体-金属/液体-金属射频连接的方式来解决这个问题。我们通过制造、测试和建模可重构的射频微带传输线来演示信道系统内的射频开关，该传输线具有集成的拉普拉斯屏障，工作在0.5-5 GHz之间。这种方法开辟了未来全液体可重构射频电子电路的潜力，其中固体和液态金属之间的物理连接被最小化或可能完全消除。

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2019 IEEE MTT-S International Microwave Symposium (IMS)

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