A Review of Ground State Hanle Effect on Paraffin Coated Alkali Atoms under EIT and EIA

Q3 Physics and Astronomy

Results in Optics Pub Date : 2024-10-11 DOI:10.1016/j.rio.2024.100753

Muhammad Jehanzaib Aslam , Muhammad Umar Farooq , Kishore Chand , M. Mustafa Azeem , Ahmer Hussain Shah

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Abstract

Introduction

This review is specifically aimed at providing deeper understanding of the ground state Hanle effect through novel methods of atomic vapor interaction with resonant light. Electromagnetically Induced Transparency (EIT) and absorption (EIA) are the primary phenomena in this context. EIT is a process in which destructive interference at absorption frequencies within a medium is caused by a control laser and makes the medium clear to the probe laser light. It should be noted that this transparency is crucial for turning on/off the light pulses, slowing down or stopping in several cases, thus enhancing the effectiveness of atomic magnetometers. However, constructive interference that occurs in EIA raises the density of the medium, which is advantageous for achieveing precise measurements. Thus, studying Hanle effect contribute in development of commercially valuable applications and the improvement of atomic clocks.

Objective

The objective of this study is to review the fundamental principles of the Hanle effect, EIT, EIA, and coating methods for alkali atoms. These principles and techniques are essential for improving the sensitivity and functionality of atomic magnetometers and other quantum devices. By understanding and applying these phenomena, significant progress has been made in the development of high-precision measurement tools and quantum technologies.

Results

Advancements in atomic magnetometer sensitivity represent a rapidly growing area of interest that has made the significant progress in the development of quantum devices. This review consolidates the state of art research and development of fundamental principles and practical applications of the Hanle effect, EIT, EIA, and coating methods for alkali atoms. It highlights how advancements in EIT and EIA have contributed to the sensitivity improvements of atomic magnetometers, and show the importance of coating methods for maintaining system integrity and performance. These developments are essential in revolutioning of modern quantum technologies and precision measurement devices.

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在EIT和EIA下对石蜡包覆碱原子基态处理效应的研究进展

本文旨在通过原子蒸气与共振光相互作用的新方法，对基态汉勒效应有更深入的了解。电磁感应透明（EIT）和吸收（EIA）是这方面的主要现象。EIT是一种由控制激光引起的介质内吸收频率的破坏性干涉，并使介质对探测激光清晰的过程。应该指出的是，这种透明度对于打开/关闭光脉冲，在某些情况下减慢或停止是至关重要的，从而提高了原子磁力计的有效性。然而，在EIA中发生的相干涉提高了介质的密度，这有利于实现精确测量。因此，研究汉勒效应有助于开发具有商业价值的应用和改进原子钟。目的综述碱原子汉乐效应的基本原理、EIT、EIA和包覆方法。这些原理和技术对于提高原子磁强计和其他量子器件的灵敏度和功能至关重要。通过理解和应用这些现象，高精度测量工具和量子技术的发展取得了重大进展。结果原子磁强计灵敏度的进步代表了一个快速增长的兴趣领域，它在量子器件的发展中取得了重大进展。本文综述了碱原子的汉勒效应、EIT、EIA和涂层方法的基本原理和实际应用的最新研究进展。它强调了EIT和EIA的进步如何有助于提高原子磁强计的灵敏度，并展示了涂层方法对保持系统完整性和性能的重要性。这些发展对现代量子技术和精密测量设备的革命至关重要。

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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