Thermoelastic Damping in Micro- and Nano-Mechanical Systems

A. Akhiezer; C. Zener; C. Zener; C. Zener; C. Zener; D. S. Greywall; D. W. Carr; E. S. Suhubi; F. J. Lockett; F. R. Blom; H. Deresiewicz; J. Q. Broughton; K. Y. Yasumura; L. D. Landau; M. A. Biot; M. Daimaruya; M. Daimaruya; M. L. Roukes; M. L. Roukes; P. Chadwick; P. Chadwick; R. E. Mihailovich; R.-C. Shieh; R.-C. Shieh; Ron Lifshitz

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Thermoelastic Damping in Micro- and Nano-Mechanical Systems

Authors: A. Akhiezer
C. Zener
C. Zener
C. Zener
C. Zener
D. S. Greywall
D. W. Carr
E. S. Suhubi
F. J. Lockett
F. R. Blom
H. Deresiewicz
J. Q. Broughton
K. Y. Yasumura
L. D. Landau
M. A. Biot
M. Daimaruya
M. Daimaruya
M. L. Roukes
M. L. Roukes
P. Chadwick
P. Chadwick
R. E. Mihailovich
R.-C. Shieh
R.-C. Shieh
Ron Lifshitz
Publication date: 17 September 1999
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The importance of thermoelastic damping as a fundamental dissipation mechanism for small-scale mechanical resonators is evaluated in light of recent efforts to design high-Q micrometer- and nanometer-scale electro-mechanical systems (MEMS and NEMS). The equations of linear thermoelasticity are used to give a simple derivation for thermoelastic damping of small flexural vibrations in thin beams. It is shown that Zener's well-known approximation by a Lorentzian with a single thermal relaxation time slightly deviates from the exact expression.Comment: 10 pages. Submitted to Phys. Rev.

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