Particle generation by laser ablation during surface decontamination

Lee, Doh-Won; Cheng, Meng‐Dawn

doi:10.1016/j.jaerosci.2004.07.007

Cited by 5 publications

(16 citation statements)

References 16 publications

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“…[11][12][13]16 Laser ablation can be applied, for example, for decontamination and decommissioning (D&D) of nuclear facilities at U.S. Department of Energy (DOE) complexes across the United States. For D&D applications, previous results 17 showed that laser ablation with an ultraviolet (UV) wavelength (266-nm) pulsed laser was most effective in particle generation compared with that with lasers of other (1064-or 532-nm) wavelengths. In this paper, the authors report, in detail, the production and transformation of particles when the UV laser was used on selected surrogate surfaces: Portland cement (cement) with or without a toxic heavy metal, chromium (Cr), prepared under laboratory conditions, stainless steel 316, and pure alumina (Al 2 O 3 ).…”

Section: Introductionmentioning

confidence: 99%

Particle Generation by Ultraviolet-Laser Ablation during Surface Decontamination

Lee

Cheng

2006

Journal of the Air & Waste Management Association

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A novel photonic decontamination method was developed for removal of pollutants from material surfaces. Such a method relies on the ability of a high-energy laser beam to ablate materials from a contaminated surface layer, thus producing airborne particles. In this paper, the authors presented the results obtained using a scanning mobility particle sizer (SMPS) system and an aerosol particle sizer (APS). Particles generated by laser ablation from the surfaces of cement, chromium-embedded cement, and alumina were experimentally investigated. Broad particle distributions from nanometer to micrometer in size were measured. For stainless steel, virtually no particle Ͼ500 nm in aerodynamic size was detected. The generated particle number concentrations of all three of the materials were increased as the 266-nm laser fluence (millijoules per square centimeter) increased. Among the three materials tested, cement was found to be the most favorable for particle removal, alumina next, and stainless steel the least. Chromium (dropped in cement) showed almost no effects on particle production. For all of the materials tested except for stainless steel, bimodal size distributions were observed; a smaller mode peaked at ϳ50 -70 nm was detected by SMPS and a larger mode (peaked at ϳ0.70 -0.85 m) by APS. Based on transmission electron microscopy observations, the authors concluded that particles in the range of 50 -70 nm were aggregates of primary particles, and those of size larger than a few hundred nanometers were produced by different mechanisms, for example, massive object ejection from the material surfaces. INTRODUCTIONLaser ablation is defined as the removal of material by laser irradiation from a surface of the material. Removed materials may be in the form of particulate matter, solid and/or liquid, and vapors. The interaction of high-power lasers with solid materials causes material removal through processes such as laser vaporization, desorption, sputtering, ejection, etching, spallation, and plasma generation. [1][2][3][4][5][6][7][8] Besides continuous research on laser ablation mechanisms, an enormous amount of research on applications using laser ablation has been performed. 9 -15 One recent and effective application is surface decontamination and cleaning. [11][12][13]16 Laser ablation can be applied, for example, for decontamination and decommissioning (D&D) of nuclear facilities at U.S. Department of Energy (DOE) complexes across the United States. For D&D applications, previous results 17 showed that laser ablation with an ultraviolet (UV) wavelength (266-nm) pulsed laser was most effective in particle generation compared with that with lasers of other (1064-or 532-nm) wavelengths. In this paper, the authors report, in detail, the production and transformation of particles when the UV laser was used on selected surrogate surfaces: Portland cement (cement) with or without a toxic heavy metal, chromium (Cr), prepared under laboratory conditions, stainless steel 316, and pure alumina (Al 2 O 3 ). The f...

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Section: Introductionmentioning

confidence: 99%

Particle Generation by Ultraviolet-Laser Ablation during Surface Decontamination

Lee

Cheng

2006

Journal of the Air & Waste Management Association

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“…This second source was based on the design of Lin and Cheng (2002), Cheng (2004a and2004b), and Cheng et al (2006) using a laser--induced breakdown instead of pulsed electrical breakdown to generate transition plasma. Note that laser--induced plasma contains higher number (~ 10 19 ) of electrons and ions than that of electrical plasma by one to two orders of magnitude; thus, theoretically, we could provide a more effective plasma source than the electrical power.…”

Section: Description Of Laboratory--scaled Nonthermal Plasma Sourcesmentioning

confidence: 99%

Testing Nonthermal Plasma for Decontamination of Sensitive Weapons Platforms and Systems

Cheng¹

2011

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“…However, characteristics of particles generated by laser ablation are not fully known. Therefore, the studies of particle concentration and their size distribution are hot topics in current laser ablation investigations recently [1][2][3][4][5][6][7][8][9]. Nanoparticle generation by laser ablation is used for a variety of applications such as biotechnology, electronic industry, etc.…”

Section: Introductionmentioning

confidence: 99%

“…Nanoparticle generation by laser ablation is used for a variety of applications such as biotechnology, electronic industry, etc. The laser ablation is also an intensive source of submicron particle generation and their possible leakage into ambient air, therefore investigations of the particle formation kinetics in ambient air during laser processing are essential for the evaluation of potential generation of particle emission and their impact on human health [7]. For example, during laser processing particles formed of metals (e. g. iron, aluminium), especially toxic (e. g. manganese, zinc) or carcinogenic substances (e. g. chromium (VI) compounds, nickel), might penetrate into a human organism and cause health concerns [8,9].…”

Section: Introductionmentioning

confidence: 99%

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Generation of metal nanoparticles by laser ablation

Dudoitis¹,

Ulevičius²,

Račiukaitis³

et al. 2011

Lith. J. Phys.

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The process of nanoparticle generation during nanosecond and picosecond laser ablation of various metals (Ni, Al, W, and stainless steel) in ambient air and argon gas was investigated. The number concentration of nanoparticles generated by laser ablation in argon gas was up to 100 times higher compared to that in ambient air. Three stable separate size peaks of nucleation, Aitken, and accumulation modes of nanoparticles were observed in case of argon gas, while in ambient air particles of a wide size spectrum (8-200 nm) were generated. The natural precursors in ambient air can have an effect on the size spectrum of particles composed of various chemical compounds with target material during the ablation process. The influence of laser process parameters and properties of investigated metals on the number concentration and size distribution of nanoparticles generated during ns-and ps-laser ablation was observed.

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Particle generation by laser ablation during surface decontamination

Cited by 5 publications

References 16 publications

Particle Generation by Ultraviolet-Laser Ablation during Surface Decontamination

Particle Generation by Ultraviolet-Laser Ablation during Surface Decontamination

Testing Nonthermal Plasma for Decontamination of Sensitive Weapons Platforms and Systems

Generation of metal nanoparticles by laser ablation

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