Transformation of Bell states using linear optics

Q2 Physics and Astronomy Physics Open Pub Date : 2023-12-08 DOI:10.1016/j.physo.2023.100199

Sarika Mishra , R.P. Singh

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Abstract

Bell states form a complete set of four maximally polarization entangled two-qubit quantum state. Being a key ingredient of many quantum applications such as entanglement based quantum key distribution protocols, superdense coding, quantum teleportation, entanglement swapping etc, Bell states have to be prepared and measured. Spontaneous parametric down-conversion (SPDC) is the easiest way of preparing Bell states and a desired Bell state can be prepared from any entangled photon pair through single-qubit logic gates. In this paper, we present the generation of complete set of Bell states, only by applying unitary transformations of half-wave plate (HWP) on the initial Bell state. The initial Bell state is prepared using a combination of a nonlinear crystal and a beam-splitter (BS) and the rest of the Bell states are created by applying single-qubit logic gates on the entangled photon pairs using HWPs. Our results can be useful in many quantum applications, especially in superdense coding where control over basis of maximally entangled state is required.

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利用线性光学转换贝尔态

贝尔态是由四个最大极化纠缠的双量子比特量子态组成的完整集合。贝尔态是许多量子应用（如基于纠缠的量子密钥分发协议、超密集编码、量子远距传输、纠缠交换等）的关键要素，因此必须对贝尔态进行制备和测量。自发参量下变频（SPDC）是制备贝尔态的最简单方法，通过单量子比特逻辑门可以从任何纠缠光子对中制备出所需的贝尔态。在本文中，我们介绍了仅通过对初始贝尔态应用半波板（HWP）的单元变换就能生成整套贝尔态的方法。初始贝尔态是用非线性晶体和分光镜（BS）组合制备的，其余的贝尔态则是通过在使用 HWP 的纠缠光子对上应用单量子比特逻辑门产生的。我们的成果可用于许多量子应用，尤其是需要控制最大纠缠态基础的超密集编码。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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