Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO3

Martin Lee; Johannes R. Renshof; Kasper J. van Zeggeren; Maurits J.A. Houmes; Edouard Lesne; Makars Šiškins; Thierry C. van Thiel; Ruben H. Guis; Mark R. van Blankenstein; Gerard J. Verbiest; Andrea D. Caviglia; Herre S.J. van der Zant; Peter G. Steeneken

doi:10.1002/adma.202204630

Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO₃

Martin Lee^*, Johannes R. Renshof, Kasper J. van Zeggeren, Maurits J.A. Houmes, Edouard Lesne, Makars Šiškins, Thierry C. van Thiel, Ruben H. Guis, Mark R. van Blankenstein, Gerard J. Verbiest, Andrea D. Caviglia, Herre S.J. van der Zant, Peter G. Steeneken

^*Corresponding author for this work

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

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Abstract

Suspended piezoelectric thin films are key elements enabling high-frequency filtering in telecommunication devices. To meet the requirements of next-generation electronics, it is essential to reduce device thickness for reaching higher resonance frequencies. Here, the high-quality mechanical and electrical properties of graphene electrodes are combined with the strong piezoelectric performance of the free-standing complex oxide, BaTiO₃ (BTO), to create ultrathin piezoelectric resonators. It is demonstrated that the device can be brought into mechanical resonance by piezoelectric actuation. By sweeping the DC bias voltage on the top graphene electrode, the BTO membrane is switched between the two poled ferroelectric states. Remarkably, ferroelectric hysteresis is also observed in the resonance frequency, magnitude and Q-factor of the first membrane mode. In the bulk acoustic mode, the device vibrates at 233 GHz. This work demonstrates the potential of combining van der Waals materials with complex oxides for next-generation electronics, which not only opens up opportunities for increasing filter frequencies, but also enables reconfiguration by poling, via ferroelectric memory effect.

Original language	English
Article number	2204630
Number of pages	9
Journal	Advanced Materials
Volume	34
Issue number	44
DOIs	https://doi.org/10.1002/adma.202204630
Publication status	Published - 2022

Keywords

2D materials
actuators
complex oxides
ferroelectrics
nano-electromechanical systems
piezoelectrics
resonators

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10.1002/adma.202204630

Advanced Materials - 2022 - Lee - Ultrathin Piezoelectric Resonators Based on Graphene and Free%E2%80%90Standing Single%E2%80%90CrystalFinal published version, 1.88 MBLicence: CC BY

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Lee, M., Renshof, J. R., van Zeggeren, K. J., Houmes, M. J. A., Lesne, E., Šiškins, M., van Thiel, T. C., Guis, R. H., van Blankenstein, M. R., Verbiest, G. J., Caviglia, A. D., van der Zant, H. S. J., & Steeneken, P. G. (2022). Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO₃. Advanced Materials, 34(44), Article 2204630. https://doi.org/10.1002/adma.202204630

@article{ccec2b690c6c4f37b98e34c708676bef,

title = "Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO3",

abstract = "Suspended piezoelectric thin films are key elements enabling high-frequency filtering in telecommunication devices. To meet the requirements of next-generation electronics, it is essential to reduce device thickness for reaching higher resonance frequencies. Here, the high-quality mechanical and electrical properties of graphene electrodes are combined with the strong piezoelectric performance of the free-standing complex oxide, BaTiO3 (BTO), to create ultrathin piezoelectric resonators. It is demonstrated that the device can be brought into mechanical resonance by piezoelectric actuation. By sweeping the DC bias voltage on the top graphene electrode, the BTO membrane is switched between the two poled ferroelectric states. Remarkably, ferroelectric hysteresis is also observed in the resonance frequency, magnitude and Q-factor of the first membrane mode. In the bulk acoustic mode, the device vibrates at 233 GHz. This work demonstrates the potential of combining van der Waals materials with complex oxides for next-generation electronics, which not only opens up opportunities for increasing filter frequencies, but also enables reconfiguration by poling, via ferroelectric memory effect.",

keywords = "2D materials, actuators, complex oxides, ferroelectrics, nano-electromechanical systems, piezoelectrics, resonators",

author = "Martin Lee and Renshof, {Johannes R.} and {van Zeggeren}, {Kasper J.} and Houmes, {Maurits J.A.} and Edouard Lesne and Makars {\v S}i{\v s}kins and {van Thiel}, {Thierry C.} and Guis, {Ruben H.} and {van Blankenstein}, {Mark R.} and Verbiest, {Gerard J.} and Caviglia, {Andrea D.} and {van der Zant}, {Herre S.J.} and Steeneken, {Peter G.}",

year = "2022",

doi = "10.1002/adma.202204630",

language = "English",

volume = "34",

journal = "Advanced Materials",

issn = "0935-9648",

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Lee, M, Renshof, JR, van Zeggeren, KJ, Houmes, MJA, Lesne, E, Šiškins, M, van Thiel, TC, Guis, RH, van Blankenstein, MR, Verbiest, GJ , Caviglia, AD , van der Zant, HSJ & Steeneken, PG 2022, 'Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO₃', Advanced Materials, vol. 34, no. 44, 2204630. https://doi.org/10.1002/adma.202204630

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T1 - Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO3

AU - Lee, Martin

AU - Renshof, Johannes R.

AU - van Zeggeren, Kasper J.

AU - Houmes, Maurits J.A.

AU - Lesne, Edouard

AU - Šiškins, Makars

AU - van Thiel, Thierry C.

AU - Guis, Ruben H.

AU - van Blankenstein, Mark R.

AU - Verbiest, Gerard J.

AU - Caviglia, Andrea D.

AU - van der Zant, Herre S.J.

AU - Steeneken, Peter G.

PY - 2022

Y1 - 2022

N2 - Suspended piezoelectric thin films are key elements enabling high-frequency filtering in telecommunication devices. To meet the requirements of next-generation electronics, it is essential to reduce device thickness for reaching higher resonance frequencies. Here, the high-quality mechanical and electrical properties of graphene electrodes are combined with the strong piezoelectric performance of the free-standing complex oxide, BaTiO3 (BTO), to create ultrathin piezoelectric resonators. It is demonstrated that the device can be brought into mechanical resonance by piezoelectric actuation. By sweeping the DC bias voltage on the top graphene electrode, the BTO membrane is switched between the two poled ferroelectric states. Remarkably, ferroelectric hysteresis is also observed in the resonance frequency, magnitude and Q-factor of the first membrane mode. In the bulk acoustic mode, the device vibrates at 233 GHz. This work demonstrates the potential of combining van der Waals materials with complex oxides for next-generation electronics, which not only opens up opportunities for increasing filter frequencies, but also enables reconfiguration by poling, via ferroelectric memory effect.

AB - Suspended piezoelectric thin films are key elements enabling high-frequency filtering in telecommunication devices. To meet the requirements of next-generation electronics, it is essential to reduce device thickness for reaching higher resonance frequencies. Here, the high-quality mechanical and electrical properties of graphene electrodes are combined with the strong piezoelectric performance of the free-standing complex oxide, BaTiO3 (BTO), to create ultrathin piezoelectric resonators. It is demonstrated that the device can be brought into mechanical resonance by piezoelectric actuation. By sweeping the DC bias voltage on the top graphene electrode, the BTO membrane is switched between the two poled ferroelectric states. Remarkably, ferroelectric hysteresis is also observed in the resonance frequency, magnitude and Q-factor of the first membrane mode. In the bulk acoustic mode, the device vibrates at 233 GHz. This work demonstrates the potential of combining van der Waals materials with complex oxides for next-generation electronics, which not only opens up opportunities for increasing filter frequencies, but also enables reconfiguration by poling, via ferroelectric memory effect.

KW - 2D materials

KW - actuators

KW - complex oxides

KW - ferroelectrics

KW - nano-electromechanical systems

KW - piezoelectrics

KW - resonators

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M3 - Article

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SN - 0935-9648

VL - 34

JO - Advanced Materials

JF - Advanced Materials

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M1 - 2204630

ER -

Ultrathin Piezoelectric Resonators Based on Graphene and Free-Standing Single-Crystal BaTiO₃

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