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Resonant domain-wall-enhanced tunable microwave ferroelectrics

Author

Listed:
  • Zongquan Gu

    (Drexel University
    Drexel University)

  • Shishir Pandya

    (University of California at Berkeley)

  • Atanu Samanta

    (Bar-Ilan University)

  • Shi Liu

    (Carnegie Institution for Science)

  • Geoffrey Xiao

    (Drexel University)

  • Cedric J. G. Meyers

    (University of California at Santa Barbara)

  • Anoop R. Damodaran

    (University of California at Berkeley)

  • Haim Barak

    (Bar-Ilan University)

  • Arvind Dasgupta

    (University of California at Berkeley)

  • Sahar Saremi

    (University of California at Berkeley)

  • Alessia Polemi

    (Drexel University)

  • Liyan Wu

    (University of Pennsylvania)

  • Adrian A. Podpirka

    (Drexel University)

  • Alexandria Will-Cole

    (Drexel University)

  • Christopher J. Hawley

    (Drexel University)

  • Peter K. Davies

    (University of Pennsylvania)

  • Robert A. York

    (University of California at Santa Barbara)

  • Ilya Grinberg

    (Bar-Ilan University)

  • Lane W. Martin

    (University of California at Berkeley
    Lawrence Berkeley National Laboratory)

  • Jonathan E. Spanier

    (Drexel University
    Drexel University
    Drexel University)

Abstract

Ordering of ferroelectric polarization1 and its trajectory in response to an electric field2 are essential for the operation of non-volatile memories3, transducers4 and electro-optic devices5. However, for voltage control of capacitance and frequency agility in telecommunication devices, domain walls have long been thought to be a hindrance because they lead to high dielectric loss and hysteresis in the device response to an applied electric field6. To avoid these effects, tunable dielectrics are often operated under piezoelectric resonance conditions, relying on operation well above the ferroelectric Curie temperature7, where tunability is compromised. Therefore, there is an unavoidable trade-off between the requirements of high tunability and low loss in tunable dielectric devices, which leads to severe limitations on their figure of merit. Here we show that domain structure can in fact be exploited to obtain ultralow loss and exceptional frequency selectivity without piezoelectric resonance. We use intrinsically tunable materials with properties that are defined not only by their chemical composition, but also by the proximity and accessibility of thermodynamically predicted strain-induced, ferroelectric domain-wall variants8. The resulting gigahertz microwave tunability and dielectric loss are better than those of the best film devices by one to two orders of magnitude and comparable to those of bulk single crystals. The measured quality factors exceed the theoretically predicted zero-field intrinsic limit owing to domain-wall fluctuations, rather than field-induced piezoelectric oscillations, which are usually associated with resonance. Resonant frequency tuning across the entire L, S and C microwave bands (1–8 gigahertz) is achieved in an individual device—a range about 100 times larger than that of the best intrinsically tunable material. These results point to a rich phase space of possible nanometre-scale domain structures that can be used to surmount current limitations, and demonstrate a promising strategy for obtaining ultrahigh frequency agility and low-loss microwave devices.

Suggested Citation

  • Zongquan Gu & Shishir Pandya & Atanu Samanta & Shi Liu & Geoffrey Xiao & Cedric J. G. Meyers & Anoop R. Damodaran & Haim Barak & Arvind Dasgupta & Sahar Saremi & Alessia Polemi & Liyan Wu & Adrian A. , 2018. "Resonant domain-wall-enhanced tunable microwave ferroelectrics," Nature, Nature, vol. 560(7720), pages 622-627, August.
    • Handle: RePEc:nat:nature:v:560:y:2018:i:7720:d:10.1038_s41586-018-0434-2
    DOI: 10.1038/s41586-018-0434-2
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    Citations

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    Cited by:

    1. Ruitao Li & Diming Xu & Chao Du & Qianqian Ma & Feng Zhang & Xu Liang & Dawei Wang & Zhongqi Shi & Wenfeng Liu & Di Zhou, 2024. "Giant dielectric tunability in ferroelectric ceramics with ultralow loss by ion substitution design," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    2. Fan Zhang & Zhe Wang & Lixuan Liu & Anmin Nie & Yanxing Li & Yongji Gong & Wenguang Zhu & Chenggang Tao, 2024. "Atomic-scale manipulation of polar domain boundaries in monolayer ferroelectric In2Se3," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    3. Haojie Xu & Wuqian Guo & Yu Ma & Yi Liu & Xinxin Hu & Lina Hua & Shiguo Han & Xitao Liu & Junhua Luo & Zhihua Sun, 2022. "Record high-Tc and large practical utilization level of electric polarization in metal-free molecular antiferroelectric solid solutions," Nature Communications, Nature, vol. 13(1), pages 1-7, December.
    4. Jing Wang & Deshan Liang & Jing Ma & Yuanyuan Fan & Ji Ma & Hasnain Mehdi Jafri & Huayu Yang & Qinghua Zhang & Yue Wang & Changqing Guo & Shouzhe Dong & Di Liu & Xueyun Wang & Jiawang Hong & Nan Zhang, 2023. "Polar Solomon rings in ferroelectric nanocrystals," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    5. Lei Zhang & Chen Yang & Chenxi Lu & Xingxing Li & Yilin Guo & Jianning Zhang & Jinglong Lin & Zhizhou Li & Chuancheng Jia & Jinlong Yang & K. N. Houk & Fanyang Mo & Xuefeng Guo, 2022. "Precise electrical gating of the single-molecule Mizoroki-Heck reaction," Nature Communications, Nature, vol. 13(1), pages 1-11, December.

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