Laser-induced breakdown self-reversal isotopic spectrometry for isotopic analysis of lithium

Touchet, Kévin; Chartier, Fredéric; Hermann, J.; Sirven, Jean-Baptiste

doi:10.1016/j.sab.2020.105868

Cited by 11 publications

(5 citation statements)

References 39 publications

(61 reference statements)

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“…The low performance was due to the fact that the hypotheses of model validity were generally not all satisfied. Although it is now well accepted that experimental conditions can be easily found to satisfy the hypotheses of congruent ablation [40,41] and LTE [42,43], and that spatial uniformity can be reached in appropriate experimental conditions (see Section 2), the condition of optically thin emission is hardly achieved for dense laser-induced plasmas [36,44,45].…”

Section: Succesful Introduction Of First Methodsmentioning

confidence: 99%

Progress in calibration-free laser-induced breakdown spectroscopy

Hermann

Gerhard²,

Burger

et al. 2023

Spectrochimica Acta Part B: Atomic Spectroscopy

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Section: Succesful Introduction Of First Methodsmentioning

confidence: 99%

Progress in calibration-free laser-induced breakdown spectroscopy

Hermann

Gerhard²,

Burger

et al. 2023

Spectrochimica Acta Part B: Atomic Spectroscopy

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“…It was reported that bulk lithium isotopic assay can be determined using LIBS to within a 95% confidence interval in minutes to an hour for enrichment levels ranging from 3% to 85%. Laser-induced breakdown self-reversal isotopic spectrometry (LIBRIS) was developed by Touchet et al 343 that exploits the fact that the spectral width of the absorption dip of self-reversed emission line involving the ground state is much smaller than the width of the overall emission line profile. It was noted by the authors that the Doppler and Stark shift effects were observed to shift the location of the absorption feature in the self-reversed emission line; thus, matrix-matched samples must be used to construct a calibration curve as these effects depend on changes of the plasma conditions that the matrix composition strongly influences.…”

Section: Fusion Reactorsmentioning

confidence: 99%

Laser Ablation Plasmas and Spectroscopy for Nuclear Applications

Kwapis,

Borrero,

Latty

et al. 2023

Appl Spectrosc

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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: see text]) 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.

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“…However, the intense development of LIBS started much later, when reliable gain-switched pulsed laser sources became available and intensified charge-coupled devices enabled time-gated spectra recording. In the last two decades, innumerable applications have been developed in various domains [176][177][178][179]. Given the immense success of LIBS analysis on Mars [180], the technique was chosen by the American, Chinese and European space agencies for new exploration missions on the red planet starting in 2021 and 2023.…”

Section: Laser-induced Breakdown Spectroscopy (Libs)mentioning

confidence: 99%

Short-Pulse Lasers: A Versatile Tool in Creating Novel Nano-/Micro-Structures and Compositional Analysis for Healthcare and Wellbeing Challenges

et al. 2021

Self Cite

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Driven by flexibility, precision, repeatability and eco-friendliness, laser-based technologies have attracted great interest to engineer or to analyze materials in various fields including energy, environment, biology and medicine. A major advantage of laser processing relies on the ability to directly structure matter at different scales and to prepare novel materials with unique physical and chemical properties. It is also a contact-free approach that makes it possible to work in inert or reactive liquid or gaseous environment. This leads today to a unique opportunity for designing, fabricating and even analyzing novel complex bio-systems. To illustrate this potential, in this paper, we gather our recent research on four types of laser-based methods relevant for nano-/micro-scale applications. First, we present and discuss pulsed laser ablation in liquid, exploited today for synthetizing ultraclean “bare” nanoparticles attractive for medicine and tissue engineering applications. Second, we discuss robust methods for rapid surface and bulk machining (subtractive manufacturing) at different scales by laser ablation. Among them, the microsphere-assisted laser surface engineering is detailed for its appropriateness to design structured substrates with hierarchically periodic patterns at nano-/micro-scale without chemical treatments. Third, we address the laser-induced forward transfer, a technology based on direct laser printing, to transfer and assemble a multitude of materials (additive structuring), including biological moiety without alteration of functionality. Finally, the fourth method is about chemical analysis: we present the potential of laser-induced breakdown spectroscopy, providing a unique tool for contact-free and space-resolved elemental analysis of organic materials. Overall, we present and discuss the prospect and complementarity of emerging reliable laser technologies, to address challenges in materials’ preparation relevant for the development of innovative multi-scale and multi-material platforms for bio-applications.

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Laser-induced breakdown self-reversal isotopic spectrometry for isotopic analysis of lithium

Cited by 11 publications

References 39 publications

Progress in calibration-free laser-induced breakdown spectroscopy

Progress in calibration-free laser-induced breakdown spectroscopy

Laser Ablation Plasmas and Spectroscopy for Nuclear Applications

Short-Pulse Lasers: A Versatile Tool in Creating Novel Nano-/Micro-Structures and Compositional Analysis for Healthcare and Wellbeing Challenges

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