Tension tuning of sound and heat transport in graphene

H., Liu,; Lee, M.; Šiškins, Makars; Zant, Herre S. J. van der; Steeneken, Peter G.; Verbiest, G. J.

doi:10.21203/rs.3.rs-1558097/v1

Cited by 2 publications

(1 citation statement)

References 20 publications

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“…We use an interferometer setup [26,27] to measure the resonance frequency and Q factor of the fabricated resonators. An intensity-modulated blue laser (λ = 405 nm) irradiates the membrane resulting in a periodic heat flux to actuate it, while a intensityfixed red laser (λ = 633 nm) is utilized to detect the motion.…”

Section: Optothermal Drivementioning

confidence: 99%

Nanomechanical resonators fabricated by atomic layer deposition on suspended 2D materials

Liu,

Basuvalingam,

Lodha

et al. 2023

2D Mater.

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Atomic layer deposition (ALD), a layer-by-layer controlled method to synthesize ultrathin materials, provides various merits over other techniques such as precise thickness control, large area scalability and excellent conformality. Here we demonstrate the possibility of using ALD growth on top of suspended 2D materials to fabricate nanomechanical resonators. We fabricate ALD nanomechanical resonators consisting of a graphene/MoS2 heterostructure. Using AFM indentation and optothermal drive, we measure their mechanical properties including Young’s modulus, resonance frequency and quality factor, showing a lower energy dissipation compared to their exfoliated counterparts. We also demonstrate the fabrication of nanomechanical resonators by exfoliating an ALD grown NbS2 layer. This study exemplifies the potential of ALD techniques to produce high-quality suspended nanomechanical membranes, providing a promising route towards high-volume fabrication of future multilayer nanodevices and nanoelectromechanical systems.

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Section: Optothermal Drivementioning

confidence: 99%

Nanomechanical resonators fabricated by atomic layer deposition on suspended 2D materials

Liu,

Basuvalingam,

Lodha

et al. 2023

2D Mater.

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Enhanced sensitivity and tunability of thermomechanical resonance near the buckling bifurcation

Liu,

Baglioni,

Boix-Constant

et al. 2024

2D Mater.

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The high susceptibility of ultrathin two-dimensional (2D) material resonators to force and temperature makes them ideal systems for sensing applications and exploring thermomechanical coupling. Although the dynamics of these systems at high stress has been thoroughly investigated, their behaviour near the buckling transition has received less attention. Here, we demonstrate that the force sensitivity and frequency tunability of 2D material resonators are significantly enhanced near the buckling bifurcation. This bifurcation is triggered by compressive stress that we induce via thermal expansion of the devices, while measuring their dynamics via an optomechanical technique. We understand the frequency tuning of the devices through a mechanical buckling model, which allows to extract the pre-strain, central deflection and boundary compressive stress of the membrane. Surprisingly, we obtain a remarkable enhancement of up to 14× the vibration amplitude attributed to a very low stiffness of the membrane at the buckling transition, as well as a high frequency tunability by temperature of more than 4.02 % /K. The presented results provide insights into the effects of buckling on the dynamics of free-standing 2D materials and thereby open up opportunities for the realization of 2D resonant sensors with buckling-enhanced sensitivity.

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Tension tuning of sound and heat transport in graphene

Cited by 2 publications

References 20 publications

Nanomechanical resonators fabricated by atomic layer deposition on suspended 2D materials

Nanomechanical resonators fabricated by atomic layer deposition on suspended 2D materials

Enhanced sensitivity and tunability of thermomechanical resonance near the buckling bifurcation

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