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便携式 诱导击穿光谱最新研究进展

曾庆栋,袁梦甜,朱志恒,陈光辉,汪婕,余华清,郭连波,李祥友

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曾庆栋, 袁梦甜, 朱志恒, 陈光辉, 汪婕, 余华清, 郭连波, 李祥友. 便携式 诱导击穿光谱最新研究进展[J]. , 2021, 14(3): 470-486. doi: 10.37188/CO.2020-0093
引用本文: 曾庆栋, 袁梦甜, 朱志恒, 陈光辉, 汪婕, 余华清, 郭连波, 李祥友. 便携式 诱导击穿光谱最新研究进展[J]. , 2021, 14(3): 470-486.doi:10.37188/CO.2020-0093
ZENG Qing-dong, YUAN Meng-tian, ZHU Zhi-heng, CHEN Guang-hui, WANG Jie, YU Hua-qing, GUO Lian-bo, LI Xiang-you. Research progress on portable laser-induced breakdown spectroscopy[J]. Chinese Optics, 2021, 14(3): 470-486. doi: 10.37188/CO.2020-0093
Citation: ZENG Qing-dong, YUAN Meng-tian, ZHU Zhi-heng, CHEN Guang-hui, WANG Jie, YU Hua-qing, GUO Lian-bo, LI Xiang-you. Research progress on portable laser-induced breakdown spectroscopy[J].Chinese Optics, 2021, 14(3): 470-486.doi:10.37188/CO.2020-0093

便携式 诱导击穿光谱最新研究进展

doi:10.37188/CO.2020-0093
基金项目:国家重大科学仪器设备开发专项(No. 2011YQ160017);国家自然科学基金项目(No. 61705064,No. 11647122);湖北省自然科学基金项目(No. 2018CFB773);湖北省教育厅团队研究项目(No. T201617)
详细信息
    作者简介:

    曾庆栋(1982—),男,湖北广水人,博士,副教授,2016年于华中科技大学获得博士学位,主要从事便携式 诱导击穿光谱的研究与开发、光谱信号处理与算法研究等方面的工作。E-mail:jerry-z@hbeu.edu.cn

    袁梦甜(1996—),女,湖北孝感人,湖北工程学院与湖北大学联合培养硕士研究生,主要从事 诱导击穿光谱、光谱分析及光谱信号处理算法的研究。E-mail:921290877@qq.com

  • 中图分类号:O433.4

Research progress on portable laser-induced breakdown spectroscopy

Funds:Supported by National Special Fund for the Development of Major Research Equipment and Instruments (No. 2011YQ160017); National Natural Science Foundation of China (No. 61705064, No. 11647122); Natural Science Foundation of Hubei Province (No. 2018CFB773); Project of the Hubei Provincial Department of Education (No. T201617)
More Information
  • 摘要:作为一种新型快速的物质成分分析技术, 诱导击穿光谱(Laser-Induced Breakdown Spectroscopy, LIBS)已经在越来越多的工业领域中被证明具有巨大的应用潜力。然而,由于野外作业或工业现场检测环境嘈杂恶劣,对仪器设备的尺寸和抗恶劣环境的能力提出了更高的要求。近年来,新型 器的发展进一步促进了LIBS仪器化的进程,使得其逐渐从实验室迈向工业应用,同时也使得LIBS系统逐渐趋于仪器化、专业化、便携化。本文综述了便携式LIBS的发展历程,对各种 光源(小型Nd:YAG固体 器、二极管泵浦固体 器、微片 器、光纤 器以及光纤传能的方案)应用于便携式LIBS系统的最新研究进展进行了综述和分类讨论,探讨了当前便携式LIBS存在的基本问题,并对其未来发展趋势进行了展望。

  • 图 1 诱导击穿光谱系统原理图

    Figure 1.Principle diagram of LIBS system

    图 2世界上第一台便携式LIBS系统(Nd:YAG, 1064 nm, 15~20 mJ/pulse, 4~8 ns)[19]

    Figure 2.The first portable LIBS system in the world (Nd:YAG, 1064 nm, 15~20 mJ/pulse, 4~8 ns)[19]

    图 3Laserna等人研发的两种便携式LIBS设备:(a)箱式(Nd: YAG, 1064 nm, 50 mJ/pulse, 6.5 ns)[26], (b)背包式 (Nd: YAG, 1064 nm, 50 mJ/pulse, 10 ns)[27]

    Figure 3.Two types of portable LIBS equipment developed by Lasernaet al. : (a) a box type (Nd: YAG, 1064 nm, 50 mJ/pulse, 6.5 ns)[26], (b) a backpack type (Nd: YAG, 1064 nm, 50 mJ/pulse, 10 ns)[27]

    图 4SECOPTA公司生产的FiberLIBS(总体积:44.9 cm×52 cm×17.7 cm,探测头:35.5 cm×16.5 cm×10 cm, 1 kg)[42]

    Figure 4.FiberLIBS produced by SECOPTA (total volume: 44.9 cm×52 cm×17.7 cm, probe head: 35.5 cm×16.5 cm×10 cm, 1 kg)[42]

    图 5华中科技大学曾晓雁、李祥友等人研制的便携式LIBS样机[48]

    Figure 5.The portable LIBS system prototype developed by Xiaoyan Zeng and Xiangyou Liet al. in Huazhong University of Science and Technology[48]

    图 6光纤 器实物图

    Figure 6.Picture of fiber laser

    图 7Gravel等人采用光纤 器和紧凑型光谱仪搭建的LIBS系统[52]

    Figure 7.The LIBS system developed by Gravelet al. using a fiber laser and a compact spectrometer[52]

    图 8德国Noll等人开发的移动式LIBS系统[53]

    Figure 8.The mobile LIBS system developed by Nollet al. in Germany[53]

    图 9华中科技大学曾庆栋、李祥友等人采用光纤 器搭建的便携式LIBS系统[54-55]

    Figure 9.The portable LIBS system using a fiber laser developed by Qingdong Zeng and Xiangyou Liet al. in Huazhong University of Science and Technology[54-55]

    图 10Whitehouse等人设计的FO-LIBS原理图[58]

    Figure 10.Schematic of FO-LIBS developed by Whitehouseet al.[58]

    图 11华中科技大学曾庆栋、李祥友等人研制的光纤传能移动式LIBS[18,61]

    Figure 11.The mobile LIBS developed by Qingdong Zeng and Xiangyou Liet al. in Huazhong University of Science and Technology[18,61]

    图 12英国牛津mPulse手持式LIBS合金分析仪[63]

    Figure 12.The mPulse handheld LIBS alloy analyzer, Oxford, UK[63]

    图 13美国Rigaku公司研发的型号为KT-100S的手持式LIBS分析仪[64]

    Figure 13.KT-100S handheld LIBS analyzer from Rigaku, USA[64]

    图 14四川大学段忆翔教授等人研发的手持式LIBS[65]

    Figure 14.The handheld LIBS developed by Yixiang Duanet al.in Sichuan University[65]

    图 15必达泰克公司的手持式μ-LIBS分析仪[67]

    Figure 15.The handheld μ-LIBS instrument of B&W Tek, Inc.[67]

    表 1基于DPSS 器、光纤 器和光纤传能的便携式LIBS的比较

    Table 1.The comparison of several kinds of LIBS systems based on a DPSS laser, a fiber laser and FO-LIBS

    优点 缺点 分析性能 适用领域
    DPSS 器 工作寿命长、功耗低、
    自然冷却、小巧便携
    能量较低、谱线波动性较大 生铁中Mn、V、Ti和Cr元素的LOD分别为171 μg/g、128 μg/g、99 μg/g和
    59 μg/g,R2分别为0.994、0.996、
    0.994和0.991[2]
    手持式野外测量、电池
    供电、原位测量
    光纤 器 抗恶劣环境、体积小、
    价格便宜
    连续背景干扰、烧蚀坑深,
    破坏性较大
    铝基中Mg的LOD为1.1 μg/g,R2=0.994;黄铜中Ni的LOD为21.3 ug/g,R2=0.997[52];生铁中的Mn、V,Si的LOD分别为195 μg/g、48 μg/g和110 μg/g,R2分别为0.997、0.991和0.992[54] 工厂、矿山等恶劣工作
    环境,在线测量
    光纤传能 避免复杂光路系统和外界
    干扰、降低自吸收效应
    能量低,LOD较差 生铁中Mn和Ti元素LOD分别为1219 μg/g, 257 μg/g,R2分别为0.997, 0.998[61] 在线、原位测量,
    移动式测量
    下载: 导出CSV

    表 2几种手持式LIBS的参数比较

    Table 2.Parameters of several handheld LIBS

    型号 研发单位 光源 体积、重量 参数及性能
    LEA Handheld LIBS[62] 芬兰Lasersec Systems公司 DPSS 器 22.6 cm×9 cm×29 cm,
    1.75 kg
    平均功率0.5 W,光谱范围220~400 nm,续航2 h,LOD可达到μg/g级,可用于爆炸物、金属、食品与药品分类。
    MPulse[63] 英国牛津公司 准连续固体调Q 9 cm×23 cm×21 cm,
    1.8 kg
    频率4 kHz,峰值功率小于0.5 W,电池支持250次测试,可用于合金鉴别与金属分拣。
    高能手持式LIBS[65] 四川大学 被动调Q的Nd: YAG
    33 cm×11 cm×32 cm,
    2.95 kg
    单脉冲能量达100 mJ,光谱范围220~397 nm,可元素定量测定,岩屑岩性识别等。
    KT-100S[64] 美国Rigaku公司 波长1064 nm的3B级
    24.3 cm×8.4 cm×25.7 cm,
    1.5 kg
    光谱范围200~480 nm,分辨率小于0.2 nm,电池供电10 h,可用于样品分类。
    ChemLite[66] 美国TSI公司 波长1574 nm的人眼安全 器 30.5 cm×25.4 cm×10.2 cm,
    2.4 kg
    1574 nm人眼安全波长,光谱范围200~700 nm,一次充电支持1300次检测,探测范围低至0.01%。
    μ-LIBS[67] 必达泰克公司 DPSS 器 27.9 cm×8.9 cm×27.9 cm,
    1.8 kg
    最大输出功率200 mW,脉宽小于1 ns,脉冲频率2 kHz,波长范围185~680 nm,分辨率0.4 nm。
    z-200c+手持式LIBS
    分析仪[68]
    SciAps公司 波长1064 nm的Nd: YAG 器 21 cm×30 cm×12 cm,
    1.82 kg
    脉宽1~2 ns,单脉冲能量5.5 mJ,重复频率50 Hz,光谱范围190~620 nm,用于原位分析钢中C含量。
    下载: 导出CSV
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  • 收稿日期:2020-05-25
  • 修回日期:2020-06-15
  • 网络出版日期:2021-04-30
  • 刊出日期:2021-05-14

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