Rapid advances are being made toward optically cooling a single mode of a micro-mechanical system to its quantum ground state and observing quantum behavior at macroscopic scales. Reaching this regime in room-temperature environments requires a stringent condition on the mechanical quality factor Qm and frequency fm, Qmfm≳kBTbath/h, which so far has been marginally satisfied only in a small number of systems. Here we propose and analyze a new class of systems that should enable unprecedented Qmfm values. The technique is based upon using optical forces to "trap" and stiffen the motion of a tethered mechanical structure, thereby freeing the resultant mechanical frequencies and decoherence rates from underlying material properties.
@article{arxiv.1101.0146,
title = {Ultrahigh-Q mechanical oscillators through optical trapping},
author = {D. E. Chang and K. -K. Ni and O. Painter and H. J. Kimble},
journal= {arXiv preprint arXiv:1101.0146},
year = {2011}
}