Topological phase induced by distinguishing parameter regimes in cavity
optomechanical system with multiple mechanical resonators
- URL: http://arxiv.org/abs/1912.13231v1
- Date: Tue, 31 Dec 2019 09:15:47 GMT
- Title: Topological phase induced by distinguishing parameter regimes in cavity
optomechanical system with multiple mechanical resonators
- Authors: Lu Qi, Yan Xing, Shutian Liu, Shou Zhang, Hong-Fu Wang
- Abstract summary: We propose two kinds of distinguishing parameter regimes to induce topological Su-Schrieffer-Heeger phase in a 1D cavity optomechanical system.
We find that the tight-binding Hamiltonian can be mapped into a topological SSH phase via modifying the Bessel function.
We also construct an analogous bosonic Kitaev model with the trivial topology by keeping the Stokes heating processes.
- Score: 6.3760138846264685
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We propose two kinds of distinguishing parameter regimes to induce
topological Su-Schrieffer-Heeger (SSH) phase in a one dimensional (1D)
multi-resonator cavity optomechanical system via modulating the frequencies of
both cavity fields and resonators. The introduction of the frequency
modulations allows us to eliminate the Stokes heating process for the mapping
of the tight-binding Hamiltonian without usual rotating wave approximation,
which is totally different from the traditional mapping of the topological
tight-binding model. We find that the tight-binding Hamiltonian can be mapped
into a topological SSH phase via modifying the Bessel function originating from
the frequency modulations of cavity fields and resonators, and the induced SSH
phase is independent on the effective optomechanical coupling strength. On the
other hand, the insensitivity of the system to the effective optomechanical
coupling provides us another new path to induce the topological SSH phase based
on the present 1D cavity optomechanical system. And we show that the system can
exhibit a topological SSH phase via varying the effective optomechanical
coupling strength in an alternative way, which is much more easier to be
achieved in experiment. Furthermore, we also construct an analogous bosonic
Kitaev model with the trivial topology by keeping the Stokes heating processes.
Our scheme provides a steerable platform to investigate the effects of
next-nearest-neighboring interactions on the topology of the system.
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