Tension-induced nonlinearities of flexural modes in nanomechanical resonators

Khan, Raphaël; Massel, Francesco; Heikkilä, Tero T.

doi:10.1103/physrevb.87.235406

Cited by 10 publications

(14 citation statements)

References 28 publications

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“…The nonlinear intrinsic coupling between the flexural–flexural, torsional–torsional and flexural–torsional modes of a microcantilever was experimentally reported in [ 351 ]. The direct bending-induced nonlinearities can be identified to facilitate the precise tuning of nanomechanical resonators [ 352 ].…”

Section: Active Frequency Tuning Methodsmentioning

confidence: 99%

Tunable Micro- and Nanomechanical Resonators

Zhang

Peng

et al. 2015

Sensors

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Advances in micro- and nanofabrication technologies have enabled the development of novel micro- and nanomechanical resonators which have attracted significant attention due to their fascinating physical properties and growing potential applications. In this review, we have presented a brief overview of the resonance behavior and frequency tuning principles by varying either the mass or the stiffness of resonators. The progress in micro- and nanomechanical resonators using the tuning electrode, tuning fork, and suspended channel structures and made of graphene have been reviewed. We have also highlighted some major influencing factors such as large-amplitude effect, surface effect and fluid effect on the performances of resonators. More specifically, we have addressed the effects of axial stress/strain, residual surface stress and adsorption-induced surface stress on the sensing and detection applications and discussed the current challenges. We have significantly focused on the active and passive frequency tuning methods and techniques for micro- and nanomechanical resonator applications. On one hand, we have comprehensively evaluated the advantages and disadvantages of each strategy, including active methods such as electrothermal, electrostatic, piezoelectrical, dielectric, magnetomotive, photothermal, mode-coupling as well as tension-based tuning mechanisms, and passive techniques such as post-fabrication and post-packaging tuning processes. On the other hand, the tuning capability and challenges to integrate reliable and customizable frequency tuning methods have been addressed. We have additionally concluded with a discussion of important future directions for further tunable micro- and nanomechanical resonators.

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Section: Active Frequency Tuning Methodsmentioning

confidence: 99%

Tunable Micro- and Nanomechanical Resonators

Zhang

Peng

et al. 2015

Sensors

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“…The required degree of anharmonicity for the vibrating oscillators to be defined as qubits deserves a separate transmission line resonator transmon (B) voltage bias voltage bias discussion. On one hand, anharmonic contributions to the mechanical vibrational eigenstates can be experimentally implemented through the use of intrinsic mechanical nonlinearities 26,27 , or by using static external electric fields [27][28][29][30] . On the other hand, the required anharmonic shift to achieve a reliable qubit behavior amounts to about 1 MHz at least (see, e.g., the effect of this value on the gate fidelities, reported in App.…”

Section: B Mechanical Anharmonicitymentioning

confidence: 99%

Electromechanical quantum simulators

et al. 2018

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Digital quantum simulators are among the most appealing applications of a quantum computer. Here we propose a universal, scalable, and integrated quantum computing platform based on tunable nonlinear electromechanical nano-oscillators. It is shown that very high operational fidelities for single and two qubits gates can be achieved in a minimal architecture, where qubits are encoded in the anharmonic vibrational modes of mechanical nanoresonators, whose effective coupling is mediated by virtual fluctuations of an intermediate superconducting artificial atom. An effective scheme to induce large single-phonon nonlinearities in nano-electromechanical devices is explicitly discussed, thus opening the route to experimental investigation in this direction. Finally, we explicitly show the very high fidelities that can be reached for the digital quantum simulation of model Hamiltonians, by using realistic experimental parameters in state-of-the art devices, and considering the transverse field Ising model as a paradigmatic example.

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“…Such terms vanish in symmetric systems and thus depend on the degree of asymmetry in the mechanical device 21,22 , which again can be enhanced with fabrication techniques. Our approach in the following is to identify the ideal situation under which one can realize these rare Bell inequality violating states.…”

Section: Modelmentioning

confidence: 99%

Entangled-state generation and Bell inequality violations in nanomechanical resonators

et al. 2014

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We investigate theoretically the conditions under which a multi-mode nanomechanical resonator, operated as a purely mechanical parametric oscillator, can be driven into highly nonclassical states. We find that when the device can be cooled to near its ground state, and certain mode matching conditions are satisfied, it is possible to prepare distinct resonator modes in quantum entangled states that violate Bell inequalities with homodyne quadrature measurements. We analyze the parameter regimes for such Bell inequality violations, and while experimentally challenging, we believe that the realization of such states lies within reach. This is a re-imagining of a quintessential quantum optics experiment by using phonons that represent tangible mechanical vibrations.

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Tension-induced nonlinearities of flexural modes in nanomechanical resonators

Cited by 10 publications

References 28 publications

Tunable Micro- and Nanomechanical Resonators

Tunable Micro- and Nanomechanical Resonators

Electromechanical quantum simulators

Entangled-state generation and Bell inequality violations in nanomechanical resonators

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