Abstract

In the past 5 years interest has soared in the inductively coupled plasma (ICP) as an excitation source for optical emission spectrochemical analysis. As a result, the ICP has rapidly made the transition from research laboratory to industrial application facility and the number of ICP users has grown correspondingly. This report describes a simple yet effective technique to aid users in constructing, modifying, and repairing the most important component in their ICP system—the plasma torch.

Nitrogen thermometry in an inductively coupled plasma torch using broadband nanosecond coherent anti-Stokes Raman scattering

Dan Fries, Spenser T. Stark, John S. Murray, Rajkumar Bhakta, Elijah R. Jans, Noel T. Clemens, Philip L. Varghese, and Sean P. Kearney
Appl. Opt. 62(29) 7560-7570 (2023)

Propagation characteristics of terahertz wave in inductively coupled plasma

Jinhai Sun, Yan Zheng, Jielin Shi, Yarui Zhao, Yu Li, Ding Wu, He Cai, Xutao Zhang, Xianli Zhu, Yongqiang Liu, Xinxue Sun, Zengming Chao, Hongcheng Yin, Wenqi Lu, and Hongbin Ding
Opt. Express 29(22) 35837-35847 (2021)

Refractive sapphire microlenses fabricated by chlorine-based inductively coupled plasma etching

Si-Hyun Park, Heonsu Jeon, Youn-Joon Sung, and Geun-Young Yeom
Appl. Opt. 40(22) 3698-3702 (2001)

Laser Doppler velocimetry of particles in a plasma torch

L. Mannik and S. K. Brown
Appl. Opt. 25(5) 649-652 (1986)

Multielemental analysis of prehistoric animal teeth by laser-induced breakdown spectroscopy and laser ablation inductively coupled plasma mass spectrometry

Michaela Galiová, Jozef Kaiser, Francisco J. Fortes, Karel Novotný, Radomír Malina, Lubomír Prokeš, Aleš Hrdlička, Tomáš Vaculovič, Miriam Nývltová Fišáková, Jiří Svoboda, Viktor Kanický, and Javier J. Laserna
Appl. Opt. 49(13) C191-C199 (2010)