Optically driven ultra-stable nanomechanical rotor

Stefan Kuhn; Benjamin A. Stickler; Alon Kosloff; Fernando Patolsky; Klaus Hornberger; Markus Arndt; James Millen

doi:10.1038/s41467-017-01902-9

Optically driven ultra-stable nanomechanical rotor

Stefan Kuhn, Benjamin A. Stickler, Alon Kosloff, Fernando Patolsky, Klaus Hornberger, Markus Arndt, James Millen

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

98 Citations (Scopus)

98 Downloads (Pure)

Abstract

Nanomechanical devices have attracted the interest of a growing interdisciplinary research community, since they can be used as highly sensitive transducers for various physical quantities. Exquisite control over these systems facilitates experiments on the foundations of physics. Here, we demonstrate that an optically trapped silicon nanorod, set into rotation at MHz frequencies, can be locked to an external clock, transducing the properties of the time standard to the rod’s motion with a remarkable frequency stability f r/Δf r of 7.7 × 1011. While the dynamics of this periodically driven rotor generally can be chaotic, we derive and verify that stable limit cycles exist over a surprisingly wide parameter range. This robustness should enable, in principle, measurements of external torques with sensitivities better than 0.25 zNm, even at room temperature. We show that in a dilute gas, real-time phase measurements on the locked nanorod transduce pressure values with a sensitivity of 0.3%.

Original language	English
Article number	1670
Journal	Nature Communications
Volume	8
Issue number	1
Early online date	21 Nov 2017
DOIs	https://doi.org/10.1038/s41467-017-01902-9
Publication status	Published - Nov 2017

Access to Document

10.1038/s41467-017-01902-9Licence: CC BY

Optically driven ultra-stable_KUHN_Accepted25October2017_GOLD VoR (CC BY)Final published version, 728 KBLicence: CC BY

Cite this

@article{2c3c9d93eb6f462d92d9af9acefc40aa,

title = "Optically driven ultra-stable nanomechanical rotor",

abstract = "Nanomechanical devices have attracted the interest of a growing interdisciplinary research community, since they can be used as highly sensitive transducers for various physical quantities. Exquisite control over these systems facilitates experiments on the foundations of physics. Here, we demonstrate that an optically trapped silicon nanorod, set into rotation at MHz frequencies, can be locked to an external clock, transducing the properties of the time standard to the rod{\textquoteright}s motion with a remarkable frequency stability f r/Δf r of 7.7 × 1011. While the dynamics of this periodically driven rotor generally can be chaotic, we derive and verify that stable limit cycles exist over a surprisingly wide parameter range. This robustness should enable, in principle, measurements of external torques with sensitivities better than 0.25 zNm, even at room temperature. We show that in a dilute gas, real-time phase measurements on the locked nanorod transduce pressure values with a sensitivity of 0.3%.",

author = "Stefan Kuhn and Stickler, {Benjamin A.} and Alon Kosloff and Fernando Patolsky and Klaus Hornberger and Markus Arndt and James Millen",

year = "2017",

month = nov,

doi = "10.1038/s41467-017-01902-9",

language = "English",

volume = "8",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Nature Publishing Group",

number = "1",

}

TY - JOUR

T1 - Optically driven ultra-stable nanomechanical rotor

AU - Kuhn, Stefan

AU - Stickler, Benjamin A.

AU - Kosloff, Alon

AU - Patolsky, Fernando

AU - Hornberger, Klaus

AU - Arndt, Markus

AU - Millen, James

PY - 2017/11

Y1 - 2017/11

N2 - Nanomechanical devices have attracted the interest of a growing interdisciplinary research community, since they can be used as highly sensitive transducers for various physical quantities. Exquisite control over these systems facilitates experiments on the foundations of physics. Here, we demonstrate that an optically trapped silicon nanorod, set into rotation at MHz frequencies, can be locked to an external clock, transducing the properties of the time standard to the rod’s motion with a remarkable frequency stability f r/Δf r of 7.7 × 1011. While the dynamics of this periodically driven rotor generally can be chaotic, we derive and verify that stable limit cycles exist over a surprisingly wide parameter range. This robustness should enable, in principle, measurements of external torques with sensitivities better than 0.25 zNm, even at room temperature. We show that in a dilute gas, real-time phase measurements on the locked nanorod transduce pressure values with a sensitivity of 0.3%.

AB - Nanomechanical devices have attracted the interest of a growing interdisciplinary research community, since they can be used as highly sensitive transducers for various physical quantities. Exquisite control over these systems facilitates experiments on the foundations of physics. Here, we demonstrate that an optically trapped silicon nanorod, set into rotation at MHz frequencies, can be locked to an external clock, transducing the properties of the time standard to the rod’s motion with a remarkable frequency stability f r/Δf r of 7.7 × 1011. While the dynamics of this periodically driven rotor generally can be chaotic, we derive and verify that stable limit cycles exist over a surprisingly wide parameter range. This robustness should enable, in principle, measurements of external torques with sensitivities better than 0.25 zNm, even at room temperature. We show that in a dilute gas, real-time phase measurements on the locked nanorod transduce pressure values with a sensitivity of 0.3%.

U2 - 10.1038/s41467-017-01902-9

DO - 10.1038/s41467-017-01902-9

M3 - Article

SN - 2041-1723

VL - 8

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 1670

ER -

Optically driven ultra-stable nanomechanical rotor

Abstract

Access to Document

Fingerprint

Cite this