Author
Listed:
- Huilong Zhang
(University of Wisconsin–Madison
University of Wisconsin–Madison)
- Jinghao Li
(USDA Forest Service
University of Wisconsin–Madison)
- Dong Liu
(University of Wisconsin–Madison)
- Seunghwan Min
(University of Wisconsin–Madison)
- Tzu-Hsuan Chang
(University of Wisconsin–Madison
National Taiwan University)
- Kanglin Xiong
(University of Wisconsin–Madison)
- Sung Hyun Park
(Yale University)
- Jisoo Kim
(University of Wisconsin–Madison)
- Yei Hwan Jung
(University of Wisconsin–Madison)
- Jeongpil Park
(University of Wisconsin–Madison)
- Juhwan Lee
(University of Wisconsin–Madison)
- Jung Han
(Yale University)
- Linda Katehi
(Texas A&M University)
- Zhiyong Cai
(USDA Forest Service)
- Shaoqin Gong
(University of Wisconsin–Madison
University of Wisconsin–Madison
University of Wisconsin–Madison)
- Zhenqiang Ma
(University of Wisconsin–Madison
University of Wisconsin–Madison)
Abstract
Low-cost flexible microwave circuits with compact size and light weight are highly desirable for flexible wireless communication and other miniaturized microwave systems. However, the prevalent studies on flexible microwave electronics have only focused on individual flexible microwave elements such as transistors, inductors, capacitors, and transmission lines. Thinning down supporting substrate of rigid chip-based monolithic microwave integrated circuits has been the only approach toward flexible microwave integrated circuits. Here, we report a flexible microwave integrated circuit strategy integrating membrane AlGaN/GaN high electron mobility transistor with passive impedance matching networks on cellulose nanofibril paper. The strategy enables a heterogeneously integrated and, to our knowledge, the first flexible microwave amplifier that can output 10 mW power beyond 5 GHz and can also be easily disposed of due to the use of cellulose nanofibril paper as the circuit substrate. The demonstration represents a critical step forward in realizing flexible wireless communication devices.
Suggested Citation
Huilong Zhang & Jinghao Li & Dong Liu & Seunghwan Min & Tzu-Hsuan Chang & Kanglin Xiong & Sung Hyun Park & Jisoo Kim & Yei Hwan Jung & Jeongpil Park & Juhwan Lee & Jung Han & Linda Katehi & Zhiyong Ca, 2020.
"Heterogeneously integrated flexible microwave amplifiers on a cellulose nanofibril substrate,"
Nature Communications, Nature, vol. 11(1), pages 1-11, December.
Handle:
RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-16957-4
DOI: 10.1038/s41467-020-16957-4
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