高功率全固态单频连续波激光器研究进展

彭威娜; 靳丕铦; 苏静; 卢华东

doi:10.12405/j.issn.2097-1486.2022.01.004

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高功率全固态单频连续波激光器研究进展

其他 | 更新时间：2024-11-01

- 高功率全固态单频连续波激光器研究进展
- Research progress of high-power all-solid-state single-frequency continuous wave laser
- 新兴科学和技术趋势 2022年1卷第1期页码：40-48
- 作者机构：
  
  1.山西大学　光电研究所　量子光学与光量子器件国家重点实验室，山西　太原　030006
  2.山西大学　极端光学协同创新中心，山西　太原　030006
- 作者简介：
  
  [ "卢华东，男，教授；博士，博士生导师；山西省杰出青年基金获得者，山西省优秀青年学术带头人；担任山西省光学学会常务理事，中国光电材料器件网专家委员会理事，《光电技术应用》青年编委，《光学技术》青年编委；长期致力于激光技术、光量子器件等方面的实验与理论研究及高技术成果转化工作；主持和承担了包括国家重点研发计划课题、国家自然科学基金、山西省科技重大专项项目等在内的20余项国家级和省部级研究项目；先后在国内外重要学术刊物上发表论文60多篇，获批美国及中国授权发明专利20多项；曾获“山西省十大科技创新人物”“山西省科教兴晋突出贡献专家”，山西省“三晋英才”支持计划青年优秀人才，并以第一完成人获得山西省技术发明奖一等奖1项，山西省专利奖1项。E-mail：luhuadong@sxu.edu.cn" ]
- 基金信息：
  
  国家自然科学基金(61975100;62027821);山西省基础研究计划(202103021221004);山西省1331工程项目;山西省高等学校中青年拔尖创新人才支持计划
- DOI：10.12405/j.issn.2097-1486.2022.01.004
  中图分类号： TN248
- 纸质出版日期：2022-09，
  
  收稿日期：2022-04-30，
  
  修回日期：2022-07-16，
- 稿件说明：
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彭威娜,靳丕铦,苏静等.高功率全固态单频连续波激光器研究进展[J].新兴科学和技术趋势,2022,1(1):40-48.

PENG Weina, JIN Pixian, SU Jing, et al. Research progress of high-power all-solid-state single-frequency continuous wave laser. [J]. Emerging Science and Technology, 2022,1(1):40-48.
彭威娜,靳丕铦,苏静等.高功率全固态单频连续波激光器研究进展[J].新兴科学和技术趋势,2022,1(1):40-48. DOI： 10.12405/j.issn.2097-1486.2022.01.004.

PENG Weina, JIN Pixian, SU Jing, et al. Research progress of high-power all-solid-state single-frequency continuous wave laser. [J]. Emerging Science and Technology, 2022,1(1):40-48. DOI： 10.12405/j.issn.2097-1486.2022.01.004.

摘要

全固态单频连续波激光器因其具有高光束质量、低噪声、窄线宽、高相干性等优点，广泛应用于冷原子物理、精密测量、激光雷达及国防军事等领域。随着科学技术的快速发展和不断深入，传统的单频激光器输出功率较低，不能满足全固态激光器在诸多研究领域的发展需求，因此急需发展高功率的全固态单频连续波激光器。为此，本文首先对比了增益晶体形态和激光放大方式在产生高功率单频连续波激光输出时的优缺点；在此基础上，总结了课题组在全固态单频连续波激光器方面的研究进展。

Abstract

All-solid-state single-frequency continuous wave lasers have widely been applied in cold atomic physics

precision measurement

laser radar

national defense and military fields owing to their advantages of high beam quality

low noise

narrow linewidth and high coherence. With the rapid development of science and technology

the output powers of traditional single-frequency lasers are too low to meet the requirements in many research fields. Therefore

it is necessary to scale up the output powers of all-solid-state single-frequency continuous-wave lasers. This review compares the advantages and disadvantages of gain crystal types and laser amplification methods in generating high-power single-frequency continuous-wave laser output and summarizes the research progress of our research group in all-solid-state single-frequency continuous-wave lasers.

关键词

高功率全固态激光器单频输出功率

Keywords

high-powerall-solid-state lasersingle-frequencypower scaling

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