1999
DOI: 10.1063/1.124554
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Measurement of mechanical resonance and losses in nanometer scale silicon wires

Abstract: We present data on nanofabricated suspended silicon wires driven at resonance. The wires are electrostatically driven and detected optically. We have observed wires with widths as small as 45 nm and resonant frequencies as high as 380 MHz. We see a strong dependence of the resonant quality factor on the surface to volume ratio.

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Cited by 296 publications
(223 citation statements)
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“…The minimum resolvable signal is achieved at 0.1 mV drive and about 5 A sensing current. Hence, at the highest possible current of 20 A, we can detect a resonance at x c /450/4ϭ0.03 Å, or 3 ϫ10 Ϫ3 Å/ͱHz, which is consistent with our estimate based on Johnson noise from beam resistance at 4.2 K. The corresponding force sensitivity is 75 fN/ͱHz, comparable with previous schemes to detect small NEMS resonators by optical interferometry 6 and the magnetomotive method. 7 The required force to drive the beam to the nonlinearity threshold is 1.5 nN.…”
supporting
confidence: 79%
“…The minimum resolvable signal is achieved at 0.1 mV drive and about 5 A sensing current. Hence, at the highest possible current of 20 A, we can detect a resonance at x c /450/4ϭ0.03 Å, or 3 ϫ10 Ϫ3 Å/ͱHz, which is consistent with our estimate based on Johnson noise from beam resistance at 4.2 K. The corresponding force sensitivity is 75 fN/ͱHz, comparable with previous schemes to detect small NEMS resonators by optical interferometry 6 and the magnetomotive method. 7 The required force to drive the beam to the nonlinearity threshold is 1.5 nN.…”
supporting
confidence: 79%
“…Previous studies, which have largely been analytical, have been restricted to certain limiting cases of these parameters. Recently work on oscillating nanoscale systems, such as carbon nanotubes [4] and silicon nanowires [5], has opened the possibility of experimentally exploring such vibrations in entirely new regimes. In the present work, we study numerically the oscillations of a one dimensional elastic system over an extensive range of both the slack and force parameters, providing insight into the physics which separates this parameter space into three distinct regimes of behavior.…”
mentioning
confidence: 99%
“…7 were done at different temperatures. [62][63][64][65][66][67][68]3,2,69 Given what is known from electronic and photonic device physics regarding oxidation and reconstruction of the Si surface, it seems clear that the mechanical properties of the smallest NEMS devices will deviate greatly from those in bulk. It may prove quite difficult to achieve ultrahigh Q with such extreme surface-to-volume ratios, if only conventional patterning approaches are utilized.…”
Section: Principal Challenges a Pursuit Of Ultrahigh Qmentioning
confidence: 99%