English

Efficient noiseless linear amplification for light fields with larger amplitudes

Quantum Physics 2017-01-17 v2

Abstract

We suggest and investigate a scheme for non-deterministic noiseless linear amplification of coherent states using successive photon addition, (a^)2(\hat a^{\dagger})^2, where a^\hat a^\dagger is the photon creation operator. We compare it with a previous proposal using the photon addition-then-subtraction, a^a^\hat a \hat a^\dagger, where a^\hat a is the photon annihilation operator, that works as an appropriate amplifier only for weak light fields. We show that when the amplitude of a coherent state is α0.91|\alpha| \gtrsim 0.91, the (a^)2(\hat a^{\dagger})^2 operation serves as a more efficient amplifier compared to the a^a^\hat a \hat a^\dagger operation in terms of equivalent input noise. Using a^a^\hat a \hat a^\dagger and (a^)2(\hat a^{\dagger})^2 as basic building blocks, we compare combinatorial amplifications of coherent states using (a^a^)2(\hat a \hat a^\dagger)^2, a^4\hat a^{\dagger 4}, a^a^a^2\hat a \hat a^\dagger\hat a^{\dagger 2}, and a^2a^a^\hat a^{\dagger 2}\hat a \hat a^\dagger, and show that (a^a^)2(\hat a \hat a^\dagger)^2, a^2a^a^\hat a^{\dagger 2}\hat a \hat a^\dagger, and a^4\hat a^{\dagger 4} exhibit strongest noiseless properties for α0.51|\alpha| \lesssim 0.51, 0.51α1.050.51 \lesssim |\alpha| \lesssim 1.05 , and α1.05|\alpha|\gtrsim 1.05 , respectively. We further show that the (a^)2(\hat a^{\dagger})^2 operation can be used for amplifying superpositions of the coherent states. In contrast to previous studies, our work provides efficient schemes to implement a noiseless amplifier for light fields with medium and large amplitudes.

Cite

@article{arxiv.1510.08977,
  title  = {Efficient noiseless linear amplification for light fields with larger amplitudes},
  author = {Jinwoo Park and Jaewoo Joo and Alessandro Zavatta and Marco Bellini and Hyunseok Jeong},
  journal= {arXiv preprint arXiv:1510.08977},
  year   = {2017}
}

Comments

16 pages, 5 figures, to be published in Optics Express

R2 v1 2026-06-22T11:32:51.005Z