Creating and verifying a quantum superposition in a micro-optomechanical system
D Kleckner, I Pikovski, E Jeffrey, L Ament… - New Journal of …, 2008 - iopscience.iop.org
New Journal of Physics, 2008•iopscience.iop.org
Micro-optomechanical systems are central to a number of recent proposals for realizing
quantum mechanical effects in relatively massive systems. Here, we focus on a particular
class of experiments which aim to demonstrate massive quantum superpositions, although
the obtained results should be generalizable to similar experiments. We analyze in detail the
effects of finite temperature on the interpretation of the experiment, and obtain a lower bound
on the degree of non-classicality of the cantilever. Although it is possible to measure the …
quantum mechanical effects in relatively massive systems. Here, we focus on a particular
class of experiments which aim to demonstrate massive quantum superpositions, although
the obtained results should be generalizable to similar experiments. We analyze in detail the
effects of finite temperature on the interpretation of the experiment, and obtain a lower bound
on the degree of non-classicality of the cantilever. Although it is possible to measure the …
Abstract
Micro-optomechanical systems are central to a number of recent proposals for realizing quantum mechanical effects in relatively massive systems. Here, we focus on a particular class of experiments which aim to demonstrate massive quantum superpositions, although the obtained results should be generalizable to similar experiments. We analyze in detail the effects of finite temperature on the interpretation of the experiment, and obtain a lower bound on the degree of non-classicality of the cantilever. Although it is possible to measure the quantum decoherence time when starting from finite temperature, an unambiguous demonstration of a quantum superposition requires the mechanical resonator to be in or near the ground state. This can be achieved by optical cooling of the fundamental mode, which also provides a method to measure the mean phonon number in that mode. We also calculate the rate of environmentally induced decoherence and estimate the timescale for gravitational collapse mechanisms as proposed by Penrose and Diosi. In view of recent experimental advances, practical considerations for the realization of the described experiment are discussed.
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