We present a highly reflective, sub-wavelength-thick membrane resonator featuring high mechanical quality factor and discuss its applicability for cavity optomechanics. The 88.5 nm thin stoichiometric silicon-nitride membrane, designed and fabricated to combine 2D-photonic and phononic crystal patterns, reaches reflectivities up to 99.89 % and a mechanical quality factor of 2.9 × 107 at room temperature. We construct a Fabry-Perot-type optical cavity, with the membrane forming one terminating mirror. The optical beam shape in cavity transmission shows a stark deviation from a simple Gaussian mode-shape, consistent with theoretical predictions. We demonstrate optomechanical sideband cooling to mK-mode temperatures, starting from room temperature. At higher intracavity powers we observe an optomechanically induced optical bistability. The demonstrated device has potential to reach high cooperativities at low light levels desirable, for example, for optomechanical sensing and squeezing applications or fundamental studies in cavity quantum optomechanics; and meets the requirements for cooling to the quantum ground state of mechanical motion from room temperature.
We study the statistical properties of a gas of interacting bosons trapped in a box potential in two and three dimensions. Our primary focus is the characteristic temperature Tp, i.e., the temperature at which the fluctuations of the number of condensed atoms (or, in 2D, the number of motionless atoms) are maximal. Using the Fock state sampling method, we show that Tp increases due to interaction. In 3D, this temperature converges to the critical temperature in the thermodynamic limit. In 2D, we show the general applicability of the method by obtaining a generalized dependence of the characteristic temperature on the interaction strength. Finally, we discuss the experimental conditions necessary for the verification of our theoretical predictions. topics: Bose-Einstein condensate, statistical ensembles, quantum gases
The fluctuations of the atom number between a Bose-Einstein
condensate and the surrounding thermal gas have been the subject of a
long standing theoretical debate. This discussion is centered around the
appropriate thermodynamic ensemble to be used for theoretical
predictions and the effect of interactions on the observed fluctuations.
Here we introduce the so-called Fock state sampling method to solve this
classic problem of current experimental interest for weakly interacting
gases. A suppression of the predicted peak fluctuations is observed when
using a microcanonical with respect to a canonical ensemble. Moreover,
interactions lead to a shift of the temperature of peak fluctuations for
harmonically trapped gases. The absolute size of the fluctuations
furthermore depends on the total number of atoms and the aspect ratio of
the trapping potential. Due to the interplay of these effect, there is
no universal suppression or enhancement of fluctuations.
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