Resonant domain-wall-enhanced tunable microwave ferroelectrics

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. Podpirka; Alexandria Will-Cole; Christopher J. Hawley; Peter K. Davies; Robert A. York; Ilya Grinberg; Lane W. Martin; Jonathan E. Spanier

doi:10.1038/s41586-018-0434-2

Resonant domain-wall-enhanced tunable microwave ferroelectrics

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. Podpirka, Alexandria Will-Cole, Christopher J. Hawley, Peter K. Davies, Robert A. York, Ilya Grinberg, Lane W. Martin, Jonathan E. Spanier

Department of Chemistry

Research output: Contribution to journal › Article › peer-review

102 Scopus citations

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.

Original language	English
Pages (from-to)	622-627
Number of pages	6
Journal	Nature
Volume	560
Issue number	7720
DOIs	https://doi.org/10.1038/s41586-018-0434-2
State	Published - 30 Aug 2018

Bibliographical note

Publisher Copyright:
© 2018, Springer Nature Limited.

Funding

Acknowledgements Work at Drexel University and the University of California at Berkeley was supported in part by the US National Science Foundation (NSF) and the Semiconductor Research Corporation under the ‘Nanoelectronics in 2020 and Beyond’ programme grant number DMR 1124696 and by the Materials Science Division of the US Army Research Office (ARO). Z.G. and G.X. acknowledge support from the ARO under grant number W911NF-14-1-0500. A.P. and A.A.P. acknowledge support from the NSF under grant number IIP 1549668. A.W.-C. acknowledges support from the NSF under grant number DMR 1608887. C.J.H. acknowledges support from the Office of Naval Research under grant number N00014-15-11-2170. J.E.S. acknowledges support from the Air Force Office of Scientific Research under grant number FA9550-13-1-012. I.G., A.S., H.B., J.E.S. and G.X. acknowledge support from the NSF–BSF (US–Israel Binational Science Foundation) joint programme under grant numbers BSF 2016637 and CBET 1705440. S.P. and A.R.D. acknowledge support from the ARO under grant number W911NF-14-1-0104. A.R.D. also acknowledges the US Department of Energy, Office of Science, Office of Basic Energy Sciences, Materials Sciences and Engineering Division under award number DE-SC-0012375 for the development of the BST materials. A.D. acknowledges support from the NSF under grant number DMR 1708615. S.S. acknowledges support from the NSF under grant number DMR 1608938. L.W.M. acknowledges support from the US Department of Energy, Office of Science, Office of Basic Energy Sciences, Materials Sciences and Engineering Division under contract number DE-AC02-05-CH11231: Materials Project programme KC23MP for the development of new functional materials. R.A.Y. and C.J.G.M. acknowledge support from ARO under grant number W911NF-14-1-0335. Numerical GLD and phase-field simulations were carried out on Proteus, a computer cluster supported by the Drexel University Research Computing Facility.

Funders	Funder number
Drexel University Research Computing Facility
Israel Binational Science Foundation	CBET 1705440, BSF 2016637, W911NF-14-1-0104
Materials Science Division of the US Army Research Office
Office of Basic Energy Sciences
US Department of Energy
US National Science Foundation
National Science Foundation	1708615
Office of Naval Research	N00014-15-11-2170
Semiconductor Research Corporation	DMR 1124696
Air Force Office of Scientific Research	FA9550-13-1-012
Army Research Office	IIP 1549668, W911NF-14-1-0500, DMR 1608887
Office of Science
Drexel University
Division of Materials Sciences and Engineering	DE-SC-0012375, DE-AC02-05-CH11231, DMR 1608938, DMR 1708615, W911NF-14-1-0335

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Gu, Z., Pandya, S., Samanta, A., Liu, S., Xiao, G., Meyers, C. J. G., Damodaran, A. R., Barak, H., Dasgupta, A., Saremi, S., Polemi, A., Wu, L., Podpirka, A. A., Will-Cole, A., Hawley, C. J., Davies, P. K., York, R. A., Grinberg, I., Martin, L. W., & Spanier, J. E. (2018). Resonant domain-wall-enhanced tunable microwave ferroelectrics. Nature, 560(7720), 622-627. https://doi.org/10.1038/s41586-018-0434-2

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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.",

author = "Zongquan Gu and Shishir Pandya and Atanu Samanta and Shi Liu and Geoffrey Xiao and Meyers, {Cedric J.G.} and Damodaran, {Anoop R.} and Haim Barak and Arvind Dasgupta and Sahar Saremi and Alessia Polemi and Liyan Wu and Podpirka, {Adrian A.} and Alexandria Will-Cole and Hawley, {Christopher J.} and Davies, {Peter K.} and York, {Robert A.} and Ilya Grinberg and Martin, {Lane W.} and Spanier, {Jonathan E.}",

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year = "2018",

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doi = "10.1038/s41586-018-0434-2",

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Gu, Z, Pandya, S, Samanta, A, Liu, S, Xiao, G, Meyers, CJG, Damodaran, AR, Barak, H, Dasgupta, A, Saremi, S, Polemi, A, Wu, L, Podpirka, AA, Will-Cole, A, Hawley, CJ, Davies, PK, York, RA, Grinberg, I, Martin, LW & Spanier, JE 2018, 'Resonant domain-wall-enhanced tunable microwave ferroelectrics', Nature, vol. 560, no. 7720, pp. 622-627. https://doi.org/10.1038/s41586-018-0434-2

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T1 - Resonant domain-wall-enhanced tunable microwave ferroelectrics

AU - Gu, Zongquan

AU - Pandya, Shishir

AU - Samanta, Atanu

AU - Liu, Shi

AU - Xiao, Geoffrey

AU - Meyers, Cedric J.G.

AU - Damodaran, Anoop R.

AU - Barak, Haim

AU - Dasgupta, Arvind

AU - Saremi, Sahar

AU - Polemi, Alessia

AU - Wu, Liyan

AU - Podpirka, Adrian A.

AU - Will-Cole, Alexandria

AU - Hawley, Christopher J.

AU - Davies, Peter K.

AU - York, Robert A.

AU - Grinberg, Ilya

AU - Martin, Lane W.

AU - Spanier, Jonathan E.

PY - 2018/8/30

Y1 - 2018/8/30

N2 - 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.

AB - 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.

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Resonant domain-wall-enhanced tunable microwave ferroelectrics

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