Dissipative and dispersive cavity optomechanics with a frequency-dependent mirror
Physical Review A(2023)
摘要
An optomechanical microcavity can considerably enhance the interaction
between light and mechanical motion by confining light to a sub-wavelength
volume. However, this comes at the cost of an increased optical loss rate.
Therefore, microcavity-based optomechanical systems are placed in the
unresolved-sideband regime, preventing sideband-based ground-state cooling. A
pathway to reduce optical loss in such systems is to engineer the cavity
mirrors, i.e., the optical modes that interact with the mechanical resonator.
In our work, we analyze such an optomechanical system, whereby one of the
mirrors is strongly frequency-dependent, i.e., a suspended Fano mirror. This
optomechanical system consists of two optical modes that couple to the motion
of the suspended Fano mirror. We formulate a quantum-coupled-mode description
that includes both the standard dispersive optomechanical coupling as well as
dissipative coupling. We solve the Langevin equations of the system dynamics in
the linear regime showing that ground-state cooling from room temperature can
be achieved even if the cavity is per se not in the resolved-sideband regime,
but achieves effective sideband resolution through strong optical mode
coupling. Importantly, we find that the cavity output spectrum needs to be
properly analyzed with respect to the effective laser detuning to infer the
phonon occupation of the mechanical resonator. Our work also predicts how to
reach the regime of nonlinear quantum optomechanics in a Fano-based microcavity
by engineering the properties of the Fano mirror.
更多查看译文
AI 理解论文
溯源树
样例
生成溯源树,研究论文发展脉络
Chat Paper
正在生成论文摘要