Radio-frequency flexible electronics: Transistors and passives

2014 IEEE Bipolar/BiCMOS Circuits and Technology Meeting (BCTM) Pub Date : 2014-12-11 DOI:10.1109/BCTM.2014.6981296

Jung‐Hun Seo, Z. Ma, Weidong Zhou

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引用次数: 1

Abstract

Flexible electronics have customarily addressed low-frequency applications because the traditional materials for flexible electronics, such as polymer and non-crystalline inorganic semiconductors, have poor electronic properties. Fast flexible electronics that operate at radio frequencies (RF), particularly at microwave frequencies, could lead to a number of novel RF applications that rigid chip based solid-state electronics cannot easily fulfill. Single-crystal semiconductor nanomembranes that can be released from a number of wafer sources are mechanically very flexible and exhibit outstanding electronic properties that are equivalent to those of their bulk counterparts. These thin, flexible single-crystal materials can furthermore be placed, via transfer printing techniques, onto nearly any substrate, including flexible polymers, thus creating the opportunity to realize RF flexible electronics. In this paper, we will present various RF transistors made of semiconductor nanomembranes on plastic substrates, along with RF passives fabricated on the same flexible substrates. We will also elaborate on the difference between such flexible electronics and those made from thinned rigid wafers.

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射频柔性电子器件:晶体管和无源

柔性电子通常针对低频应用，因为柔性电子的传统材料，如聚合物和非晶体无机半导体，具有较差的电子性能。在射频(RF)下工作的快速柔性电子器件，特别是在微波频率下，可能会导致许多新的射频应用，这些应用是基于刚性芯片的固态电子器件无法轻易实现的。单晶半导体纳米膜可以从许多晶圆源中释放出来，在机械上非常灵活，并表现出与它们的体对应物相当的杰出电子特性。通过转移印刷技术，这些薄而灵活的单晶材料可以进一步放置在几乎任何基板上，包括柔性聚合物，从而创造了实现射频柔性电子器件的机会。在本文中，我们将介绍在塑料衬底上由半导体纳米膜制成的各种射频晶体管，以及在相同柔性衬底上制造的射频无源。我们还将详细说明这种柔性电子产品与由薄刚性晶圆制成的电子产品之间的区别。

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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2014 IEEE Bipolar/BiCMOS Circuits and Technology Meeting (BCTM)

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