Fast and efficient deterministic quantum state transfer between two remote mechanical resonators

• URL: http://arxiv.org/abs/2003.01175v1
• Date: Mon, 2 Mar 2020 20:18:54 GMT
• Title: Fast and efficient deterministic quantum state transfer between two remote mechanical resonators
• Authors: Mojtaba Rezaei, Kurosh Javidan, Hamidreza Ramezani, and Mehdi Abdi
• Abstract summary: We show that one obtains a quantum state transfer with high efficiency using adiabatic variation of the effective coupling strengths. Our results show that the shortcut to adiabaticity provides an efficient and fast quantum state transfer even for small values of the coupling strength.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: The main challenge in deterministic quantum state transfer in long-distance quantum communications is the transmission losses in the communication channel. To overcome this limitation, here we use the adiabatic theorem and find a lossless evolution path between two remote mechanical modes. By adiabatic variation of the effective coupling strengths between the two nodes and the intermediate optical channel modes, we engineer a transmission path for the quantum state transfer that is decoupled from the decaying fiber modes. Using our proposed method we show that one obtains a quantum state transfer with high efficiency. Furthermore, to bypass the slow nature of the adiabatic process and its sensitivity to the mechanical damping and noise as well as the strength of the driving pulses, we develop the shortcut to adiabatic passage protocol for our proposed quantum state transfer. Our results show that the shortcut to adiabaticity provides an efficient and fast quantum state transfer even for small values of the coupling strength. We show that the performance of our protocol for long-distance quantum communications remains efficient for transferring the quantum states between two remote mechanical resonators being hundred meters apart.

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