Laser Ablation Plasmas and Spectroscopy for Nuclear Applications

Emily H. Kwapis, Justin Borrero, Kyle S. Latty, Hunter B. Andrews, Supathorn “Supy” Phongikaroon, Kyle C. Hartig

Research output: Contribution to journalReview articlepeer-review

19 Scopus citations

Abstract

The development of measurement methodologies to detect and monitor nuclear-relevant materials remains a consistent and significant interest across the nuclear energy, nonproliferation, safeguards, and forensics communities. Optical spectroscopy of laser-produced plasmas is becoming an increasingly popular diagnostic technique to measure radiological and nuclear materials in the field without sample preparation, where current capabilities encompass the standoff, isotopically resolved and phase-identifiable (e.g., UO and UO (Formula presented.)) detection of elements across the periodic table. These methods rely on the process of laser ablation (LA), where a high-powered pulsed laser is used to excite a sample (solid, liquid, or gas) into a luminous microplasma that rapidly undergoes de-excitation through the emission of electromagnetic radiation, which serves as a spectroscopic fingerprint for that sample. This review focuses on LA plasmas and spectroscopy for nuclear applications, covering topics from the wide-area environmental sampling and atmospheric sensing of radionuclides to recent implementations of multivariate machine learning methods that work to enable the real-time analysis of spectrochemical measurements with an emphasis on fundamental research and development activities over the past two decades. Background on the physical breakdown mechanisms and interactions of matter with nanosecond and ultrafast laser pulses that lead to the generation of laser-produced microplasmas is provided, followed by a description of the transient spatiotemporal plasma conditions that control the behavior of spectroscopic signatures recorded by analytical methods in atomic and molecular spectroscopy. High-temperature chemical and thermodynamic processes governing reactive LA plasmas are also examined alongside investigations into the condensation pathways of the plasma, which are believed to serve as chemical surrogates for fallout particles formed in nuclear fireballs. Laser-supported absorption waves and laser-induced shockwaves that accompany LA plasmas are also discussed, which could provide insights into atmospheric ionization phenomena from strong shocks following nuclear detonations. Furthermore, the standoff detection of trace radioactive aerosols and fission gases is reviewed in the context of monitoring atmospheric radiation plumes and off-gas streams of molten salt reactors. Finally, concluding remarks will present future outlooks on the role of LA plasma spectroscopy in the nuclear community.

Original languageEnglish
Pages (from-to)9-55
Number of pages47
JournalApplied Spectroscopy
Volume78
Issue number1
DOIs
StatePublished - Jan 2024

Funding

The authors disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: This document is the result of research funded partially by the Department of Defense Science, Mathematics, and Research for Transformation (SMART) Scholarship-for-Service Program; US Department of Energy (DOE) National Nuclear Security Administration Monitoring, Technology, and Verification (MTV) Consortium award number DE-NA0003920 and Consortium for Nuclear Forensics award number DE-NA0004142; Defense Threat Reduction Agency Interaction of Ionizing Radiation with Matter (IIRM) University Research Alliance award number HDTRA1-20-2-0002; and DOE’s Oak Ridge National Laboratory, which is operated by UT-Battelle LLC under contract number DE-AC05-00OR22725. This work was funded by the DOE’s Office of Nuclear Energy (NE), Advanced Reactor Development Program (ARDP), MSR Program. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or any agency thereof.

Keywords

  • LIBS
  • Laser ablation
  • laser filamentation
  • laser-induced breakdown spectroscopy
  • machine learning
  • molten salts
  • nuclear
  • plasma chemistry
  • plume detection

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