@inproceedings{cd77f74a5bae4733a2f9da0685440330,
title = "Nonlinear mechanical resonators for ultra-sensitive mass detection",
abstract = "The fundamental sensitivity limit of an appropriately scaled down mechanical resonator can approach one atomic mass unit when only thermal noise is present in the system. However, operation of such nanoscale mechanical resonators is very challenging due to minuteness of their oscillation amplitudes and presence of multiple noise sources in real experimental environments. In order to surmount these challenges, we use microscale cantilever resonators driven to large amplitudes, far beyond their nonlinear instability onset. Our experiments show that such a nonlinear cantilever resonator, described analytically as a Duffing oscillator, has mass sensing performance comparable to that of much smaller resonators operating in a linear regime. We demonstrate femtogram level mass sensing that relies on a bifurcation point tracking that does not require any complex readout means. Our approaches enable straightforward detection of mass changes that are near the fundamental limit imposed by thermo-mechanical fluctuations.",
keywords = "Bifurcation point, Mass sensing, Mechanical nanoresonators, Nonlinear oscillators",
author = "Datskos, {P. G.} and Lavrik, {N. V.}",
note = "Publisher Copyright: {\textcopyright} 2014 SPIE.; Unmanned/Unattended Sensors and Sensor Networks X ; Conference date: 24-09-2014 Through 25-09-2014",
year = "2014",
doi = "10.1117/12.2071922",
language = "English",
series = "Proceedings of SPIE - The International Society for Optical Engineering",
publisher = "SPIE",
editor = "Carapezza, {Edward M.} and Christos Tsamis and Datskos, {Panos G.}",
booktitle = "Unmanned/Unattended Sensors and Sensor Networks X",
}