Time-domain control of ultrahigh-frequency nanomechanical systems

N. Liu; F. Giesen; M. Belov; J. Losby; J. Moroz; A. E. Fraser; G. McKinnon; T. J. Clement; V. Sauer; W. K. Hiebert; M. R. Freeman

doi:10.1038/nnano.2008.319

Time-domain control of ultrahigh-frequency nanomechanical systems

N. Liu, F. Giesen, M. Belov, J. Losby, J. Moroz, A. E. Fraser, G. McKinnon, T. J. Clement, V. Sauer, W. K. Hiebert, M. R. Freeman

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

Abstract

Nanoelectromechanical systems could have applications in fields as diverse as ultrasensitive mass detection and mechanical computation, and can also be used to explore fundamental phenomena such as quantized heat conductance and quantum-limited displacement. Most nanomechanical studies to date have been performed in the frequency domain. However, applications in computation and information storage will require transient excitation and high-speed time-domain operation of nanomechanical systems. Here we show a time-resolved optical approach to the transduction of ultrahigh-frequency nanoelectromechanical systems, and demonstrate that coherent control of nanomechanical oscillation is possible through appropriate pulse programming. A series of cantilevers with resonant frequencies ranging from less than 10 MHz to over 1 GHz are characterized using the same pulse parameters.

Original language	English
Pages (from-to)	715-719
Number of pages	5
Journal	Nature Nanotechnology
Volume	3
Issue number	12
DOIs	https://doi.org/10.1038/nnano.2008.319
Publication status	Published - Dec 2008
Externally published	Yes

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abstract = "Nanoelectromechanical systems could have applications in fields as diverse as ultrasensitive mass detection and mechanical computation, and can also be used to explore fundamental phenomena such as quantized heat conductance and quantum-limited displacement. Most nanomechanical studies to date have been performed in the frequency domain. However, applications in computation and information storage will require transient excitation and high-speed time-domain operation of nanomechanical systems. Here we show a time-resolved optical approach to the transduction of ultrahigh-frequency nanoelectromechanical systems, and demonstrate that coherent control of nanomechanical oscillation is possible through appropriate pulse programming. A series of cantilevers with resonant frequencies ranging from less than 10 MHz to over 1 GHz are characterized using the same pulse parameters.",

author = "N. Liu and F. Giesen and M. Belov and J. Losby and J. Moroz and Fraser, {A. E.} and G. McKinnon and Clement, {T. J.} and V. Sauer and Hiebert, {W. K.} and Freeman, {M. R.}",

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AU - Liu, N.

AU - Giesen, F.

AU - Belov, M.

AU - Losby, J.

AU - Moroz, J.

AU - Fraser, A. E.

AU - McKinnon, G.

AU - Clement, T. J.

AU - Sauer, V.

AU - Hiebert, W. K.

AU - Freeman, M. R.

PY - 2008/12

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Time-domain control of ultrahigh-frequency nanomechanical systems

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