使用Bessel光束增强相位共轭四波混频

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"使用Bessel束增强四波混频相位共轭的研究" 本文主要探讨了如何利用Bessel光束来增强相位共轭退化四波混频（DFWM）的过程，这是一种在热原子铷蒸气中发生的光学现象。四波混频是一种非线性光学效应，它涉及到四个光波在介质中的相互作用，产生新的频率成分。在这个实验中，研究人员使用了Bessel光束作为探测光束，以提升DFWM信号的强度。 Bessel光束是一种特殊的光束类型，其特点是具有轴对称的结构和无限深度的焦散特性，能够在传播过程中保持其形状不变，这使得它在许多光学应用中表现出独特的优点。在本研究中，Bessel光束是通过热非线性光学效应——交叉相位调制产生的。这种效应利用介质的热响应，当光束通过介质时，介质的温度变化会导致折射率的变化，进而产生相位调制，形成Bessel光束。实验结果显示，与传统的高斯光束相比，使用Bessel光束进行DFWM时，生成的信号强度大约是高斯光束的两倍。这种增强可以归因于Bessel光束的两个关键特征：一是其深度延伸，这意味着Bessel光束可以穿透更深的介质，增加了与介质相互作用的机会；二是其聚焦特性更为紧密，这能够提高光场在原子介质中的强度，从而增强了四波混频效应。这一发现对于优化非线性光学过程，特别是在热原子系统中的应用，具有重要意义。Bessel光束增强的DFWM不仅可能改善现有的光学通信、信息处理和传感技术，还可能为量子信息科学、光学数据存储以及高级光学成像等领域开辟新的可能性。此外，该研究也提供了对非线性光学过程更深入的理解，尤其是如何利用特殊光束形状来控制这些过程。利用Bessel光束增强相位共轭退化四波混频是一项创新的技术，它展示了非线性光学在热原子系统中的潜力，并为未来相关领域的研究和应用提供了新的途径。这项工作不仅推动了光学技术的发展，也为理解和利用非线性光学效应提供了宝贵的理论和实验基础。

Enhancement of phase conjugation degenerate

four-wave mixing using a Bessel beam

QIAN ZHANG,

1,†

XUEMEI CHENG,

,†

HAOWEI CHEN,

1,3

BO HE,

ZHAOYU REN,

YING ZHANG,

AND JINTAO BAI

State Key Laboratory Incubation Base of Photoelectric Technology and Functional Materials, National Photoelectric Technology

and Functional Materials and Application of Science and Technology International Cooperation Center,

Institute of Photonics & Photon-Technology, Northwest University, Xi’an 710069, China

School of Science, Engineering University of PAP, Xi’an 710086, China

e-mail: chenhaowei2005@126.com

*Corresponding author: xmcheng@nwu.edu.cn

Received 26 October 2017; revised 7 December 2017; accepted 22 December 2017; posted 3 January 2018 (Doc. ID 310019);

published 12 February 2018

We report on the enhancement of phase conjugation degenerate four-wave mixing (DFWM) in hot atomic Rb

vapor by using a Bessel beam as the probe beam. The Bessel beam was generated using cross-phase modulation

based on the thermal nonlinear optical effect. Our results demonstrated that the DFWM signal generated by the

Bessel beam is about twice as large as that generated by the Gaussian beam, which can be attributed to the ex-

tended depth and tight focusing features of the Bessel beam. We also found that a DFWM signal with reasonable

intensity can be detected even when the Bessel beam encounters an obstruction on its way, thanks to the self-

healing property of the Bessel beam. This work not only indicates that DFWM using a Bessel beam would be

of great potential in the fields of high-fidelity communication, adaptive optics, and so on, but also suggests that

a Bessel beam would be of significance to enhance the nonlinear process, especially in thick and scattering

media.

OCIS codes: (190.4380) Nonlinear optics, four-wave mixing; (350.6830) Thermal lensing; (060.5060) Phase modulation.

https://doi.org/10.1364/PRJ.6.000162

1. INTRODUCTION

Bessel beams are radiations of which the amplitudes can be

described by Bessel functions, which are sets of solutions to

the Helmholtz equation in free space [1]. As they exhibit the

propagation-invariant feature (non-diffraction) [2–5], people

can achieve an extended depth of field with a small focal spot

using Bessel beams. Moreover, they have the ability to reestab-

lish their transverse intensity profiles after passing through an

obstacle (self-healing, self-reconstructing). For those attractive

properties, Bessel beams have been applied in numerous areas,

such as atom optics [6,7], optical micromanipulation [2],

microscopy [8–10], and optical tweezers [11]. Bessel bea ms

are also of particular significance in nonlinear optics [12–14].

On one hand, nonlinear optical processes can be enhanced

(especially in thick and complex media) , thanks to the “non-

diffraction” and “self-reconstructing” properties of the Bessel

beam. On the other hand, more information of the nonlinear

medium can be retrieved because of the unique phase-matching

characteristics across the focal region.

Four-wave mixing (FWM) is a kind of third-order nonlinear

process in which three beams interact with the nonlinear

medium and a fourth beam (FW M signal) is generated when

the phase-matching condition is satisfied. FWM has a variety of

applications, such as squeezed states of light [15], wavelength

conversion [16], isotope selective analysis and determinat ion

[17,18], and image reconstruction [19,20]. In particular, de-

generate FWM (DFWM) is a superb method to generate a

phase-conjugate beam, in which a probe beam intersects two

counter-propagating pump beams, and the DFWM signal is

generated in the opposite direction of the probe beam.

Because the DFWM signal is the phase-conjugate beam of

the input probe beam, it can be used to eliminate the distortion

as the probe beam passes through an inhomogeneous phase-

distorting medium [21,22]. So far, DFWM has been widely used

in adaptive optics, laser communication, and so on. However,

the DFWM signal decreases or even disappears due to phase-

mismatching and loss of energy in a strongly scattering thick

medium, limiting its application in harsh environments.

In this work, we use a Bessel beam as the probe beam and

study the enhancement of DFWM in hot atomic Rb vapor.

The Bessel beam is generated by focusing the hollow beam

generated using cross-phase modulation based on the thermal

nonlinear optical effect [23]. Compared with commonly used

hollow beam generation methods (including axicon lenses [24]

162

Vol. 6, No. 3 / March 2018 / Photonics Research

Research Article

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