Phonon-tunnelling dissipation in mechanical resonators

Microscale and nanoscale mechanical resonators have recently emerged as ubiquitous devices for use in advanced technological applications, for example, in mobile communications and inertial sensors, and as novel tools for fundamental scientific endeavours. Their performance is in many cases limited by the deleterious effects of mechanical damping. In this study, we report a significant advancement towards understanding and controlling support-induced losses in generic mechanical resonators. We begin by introducing an efficient numerical solver, based on the 'phonon-tunnelling' approach, capable of predicting the design-limited damping of high-quality mechanical resonators. Further, through careful device engineering, we isolate support-induced losses and perform a rigorous experimental test of the strong geometric dependence of this loss mechanism. Our results are in excellent agreement with the theory, demonstrating the predictive power of our approach. In combination with recent progress on complementary dissipation mechanisms, our phonon-tunnelling solver represents a major step towards accurate prediction of the mechanical quality factor.

[1]  Anton Zeilinger,et al.  A quantum renaissance , 2008 .

[2]  D M Karabacak,et al.  High-frequency nanofluidics: an experimental study using nanomechanical resonators. , 2007, Physical review letters.

[3]  Christoph Simon,et al.  Towards quantum superpositions of a mirror , 2004 .

[4]  Thomas Faust,et al.  Damping of nanomechanical resonators. , 2010, Physical review letters.

[5]  Markus Aspelmeyer,et al.  Focus on Mechanical Systems at the Quantum Limit , 2008 .

[6]  A. Partridge,et al.  MEMS Oscillators for High Volume Commercial Applications , 2007, TRANSDUCERS 2007 - 2007 International Solid-State Sensors, Actuators and Microsystems Conference.

[7]  K. Vahala,et al.  Optomechanical crystals , 2009, Nature.

[8]  John A. Judge,et al.  Attachment losses of high Q oscillators , 2004 .

[9]  F. Guinea,et al.  Surface dissipation in nanoelectromechanical systems: Unified description with the standard tunneling model and effects of metallic electrodes , 2007, 0712.0753.

[10]  B. Chui,et al.  Single spin detection by magnetic resonance force microscopy , 2004, Nature.

[11]  I. Wilson-Rae,et al.  Intrinsic dissipation in nanomechanical resonators due to phonon tunneling , 2007, 0710.0200.

[12]  Sylvain Gigan,et al.  Monocrystalline AlxGa1−xAs heterostructures for high-reflectivity high-Q micromechanical resonators in the megahertz regime , 2008, 0802.0465.

[13]  Ark-Chew Wong,et al.  VHF free-free beam high-Q micromechanical resonators , 2000, Journal of Microelectromechanical Systems.

[14]  C. J. Mellor,et al.  Dissipation due to tunneling two-level systems in gold nanomechanical resonators , 2010 .

[15]  T. Kenny,et al.  Quality factors in micron- and submicron-thick cantilevers , 2000, Journal of Microelectromechanical Systems.

[16]  M. Roukes,et al.  Thermoelastic damping in micro- and nanomechanical systems , 1999, cond-mat/9909271.

[17]  Erik Lucero,et al.  Quantum ground state and single-phonon control of a mechanical resonator , 2010, Nature.

[18]  M. Roukes,et al.  Toward single-molecule nanomechanical mass spectrometry , 2005, Nature nanotechnology.

[19]  Tomi Mattila,et al.  A 12 MHz micromechanical bulk acoustic mode oscillator , 2002 .

[20]  O. Arcizet,et al.  Ultralow dissipation optomechanical resonators on a chip , 2008, CLEO/Europe - EQEC 2009 - European Conference on Lasers and Electro-Optics and the European Quantum Electronics Conference.

[21]  H. Craighead Nanoelectromechanical systems. , 2000, Science.

[22]  G. J. Iafrate,et al.  Phonon dynamics and phonon assisted losses in Euler-Bernoulli nanobeams , 2008 .

[23]  Michael R. Vanner,et al.  Demonstration of an ultracold micro-optomechanical oscillator in a cryogenic cavity , 2009, 0901.1801.

[24]  David Bindel,et al.  Elastic PMLs for resonator anchor loss simulation , 2005 .

[25]  Yong-Hwa Park,et al.  High-fidelity modeling of MEMS resonators. Part I. Anchor loss mechanisms through substrate , 2004, Journal of Microelectromechanical Systems.

[26]  Daniel Rugar,et al.  Magnetic resonance force microscopy: recent results , 1995 .

[27]  C. Zener INTERNAL FRICTION IN SOLIDS. I. THEORY OF INTERNAL FRICTION IN REEDS , 1937 .

[28]  Scott S. Verbridge,et al.  A megahertz nanomechanical resonator with room temperature quality factor over a million , 2008 .

[29]  Achim Peters,et al.  Megahertz monocrystalline optomechanical resonators with minimal dissipation , 2010, 2010 IEEE 23rd International Conference on Micro Electro Mechanical Systems (MEMS).

[30]  Scott S. Verbridge,et al.  High quality factor resonance at room temperature with nanostrings under high tensile stress , 2006 .

[31]  T. Kenny,et al.  Engineering MEMS Resonators With Low Thermoelastic Damping , 2006, Journal of Microelectromechanical Systems.

[32]  D. Rugar,et al.  Nanoscale magnetic resonance imaging , 2009, Proceedings of the National Academy of Sciences.

[33]  Miles P. Blencowe,et al.  Quantum electromechanical systems , 2004 .

[34]  A. L. Kimball,et al.  Internal Friction in Solids , 1926, Transactions of the American Society of Mechanical Engineers.

[35]  T. Kippenberg,et al.  Cavity Optomechanics: Back-Action at the Mesoscale , 2008, Science.

[36]  H. Craighead,et al.  High-Q nanomechanics via destructive interference of elastic waves. , 2010, Physical review letters.

[37]  K. Jensen,et al.  An atomic-resolution nanomechanical mass sensor. , 2008, Nature Nanotechnology.

[38]  P. M. Echternach,et al.  Nanomechanical measurements of a superconducting qubit , 2009, Nature.

[39]  Brian H. Houston,et al.  Effect of viscous loss on mechanical resonators designed for mass detection , 2006 .

[40]  Brian H. Houston,et al.  Attachment loss of micromechanical and nanomechanical resonators in the limits of thick and thin support structures , 2007 .

[41]  Michael L. Roukes,et al.  Putting mechanics into quantum mechanics , 2005 .

[42]  Markus Aspelmeyer,et al.  Free-standing AlxGa1−xAs heterostructures by gas-phase etching of germanium , 2010 .

[43]  Michael L. Roukes,et al.  Intrinsic dissipation in high-frequency micromechanical resonators , 2002 .

[44]  M. Blencowe,et al.  Entanglement and decoherence of a micromechanical resonator via coupling to a Cooper-pair box. , 2002, Physical review letters.

[45]  M. Roukes,et al.  Ultra-sensitive NEMS-based cantilevers for sensing, scanned probe and very high-frequency applications. , 2007, Nature nanotechnology.

[46]  H. Craighead,et al.  Stress and silicon nitride: a crack in the universal dissipation of glasses. , 2009, Physical review letters.

[47]  M. Cross,et al.  Elastic Wave Transmission at an Abrupt Junction in a Thin Plate, with Application to Heat Transport and Vibrations in Mesoscopic Systems , 2000, cond-mat/0011501.

[48]  M. Blencowe,et al.  Damping and decoherence of a nanomechanical resonator due to a few two-level systems , 2009, 0907.0431.

[49]  C. Nguyen,et al.  High-Q UHF micromechanical radial-contour mode disk resonators , 2005, Journal of Microelectromechanical Systems.