Laser ablation in analytical chemistry—a review

Russo, Richard E.

doi:10.1016/s0039-9140(02)00053-x

Cited by 507 publications

(341 citation statements)

References 131 publications

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“…24,[72][73][74] As a result, a UV laser pulse favors higher increasing rates of surface temperature and higher maximum surface temperatures (higher energy reaching the sample surface) and an IR laser pulse allows higher maximum plasma temperatures, higher maximum electron densities and higher plasma expansion (higher energy absorption by the plasma and greater laser-plasma interaction). 75,78 This leads, in general, to a higher ablation efficiency (amount of mass removed per unit energy delivered) and reproducibility, a lower fractionation and a lower background continuum emission when using UV lasers, as described by several papers, 27,[76][77][78][79] and lower threshold fluences (minimum fluence to achieve ablation or a measurable emission signal) when using IR lasers, as described by Cabalín and Laserna 80 in the analysis of different metals and by Gómez et al 81 in a study of removing graffitis from urban buildings. They also reported lower matrix effects due to different melting points of the metal samples and a higher removal efficiency of graffitis when using IR lasers in comparison with UV lasers.…”

Section: +mentioning

confidence: 99%

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Laser Induced Breakdown Spectroscopy

Pasquini¹,

Cortez²,

Silva³

et al. 2007

J. Braz. Chem. Soc.

323

194

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Esta revisão descreve os aspectos fundamentais, a instrumentação, as aplicações e tendências futuras de uma técnica analítica que se encontra em seu estágio de consolidação e que está em vias de estabelecer o seu nicho entre as técnicas espectrofotométricas modernas. A técnica é denominada Espectroscopia de Emissão em Plasma Induzido por Laser (em inglês, Laser Induced Breakdown Spectroscopy, LIBS) e sua principal característica está no uso de pulsos de laser como fonte de energia para vaporizar a amostra e excitar a emissão de radiação eletromagnética, a partir de seus elementos e/ou fragmentos moleculares. A radiação emitida é analisada por meio de instrumentos ópticos de alta resolução e as suas intensidades são medidas, usualmente com detectores rápidos de estado sólido. Em conjunto, esses dispositivos permitem a geração e a medida de um espectro de emissão de faixa ampla do fenômeno induzido pelo pulso de laser. O espectro registrado contém informação qualitativa e quantitativa que pode ser correlacionada com a identidade da amostra ou empregada na determinação da quantidade de seus constituintes. Essa revisão é dividida em quatro partes. A primeira aborda aspectos históricos da técnica e os conceitos teóricos relevantes associados com LIBS; então, os aspectos práticos de diversas abordagens experimentais e instrumentais empregadas na implementação da técnica são revistos de forma crítica; as aplicações encontradas na literatura, incluindo aquelas que empregam quimiometria, são classificadas e exemplificadas por meio de trabalhos relevantes recentemente publicados. Finalmente, uma tentativa de estabelecer uma avaliação global e as perspectivas futuras para a técnica é apresentada.This review describes the fundamentals, instrumentation, applications and future trends of an analytical technique that is in its early stages of consolidation and is establishing its definitive niches among modern spectrometric techniques. The technique has been named Laser Induced Breakdown Spectroscopy (LIBS) and its main characteristic stands in the use of short laser pulses as the energy source to vaporize samples and excite the emission of electromagnetic radiation from its elements and/or molecular fragments. The emitted radiation is analyzed by high resolution optics and the intensities are recorded, usually by fast triggered solid state detectors. Together, these devices allow producing and registering a wide ranging emission spectrum of the short-lived phenomenon induced by the laser pulse. The spectrum contains qualitative and quantitative information which can be correlated with sample identity or can be used to determine the amount of its constituents. This review is divided in four parts. First, the relevant historical and theoretical concepts associated with LIBS are presented; then the main practical aspects of the several experimental and instrumental approaches employed for implementation of the technique are critically described; the applications related in the literature, including those making use of chemometri...

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Section: +mentioning

confidence: 99%

“…27 It limits the amount of constituents (analytes) that will be detached from the sample by the laser pulse and introduced into the Figure 2. Sequence of events following the striking of a focused short laser pulse (ca.…”

Section: Ablationmentioning

confidence: 99%

Laser Induced Breakdown Spectroscopy

Pasquini¹,

Cortez²,

Silva³

et al. 2007

J. Braz. Chem. Soc.

323

194

View full text Add to dashboard Cite

show abstract

“…The results presented in this study represent the average of 3 laser ablation passes following pre-cleaning by a previous laser ablation scan. For the purpose of this study, we chose not to use a laser ablation standard due to the difficulties of obtaining matrix-matched traceelement standards and the strong matrix dependence of laser-fractionation [25,26]. Instead, Mg/Ca and Sr/Ca ratios were calculated directly from measured ion-beam intensities (corrected for isotopic abundance).…”

Section: In Situ Trace Metal Analysis Via La-mc-icpmsmentioning

confidence: 99%

Seasonal trace-element and stable-isotope variations in a Chinese speleothem: The potential for high-resolution paleomonsoon reconstruction

Johnson

Belshaw

et al. 2006

Earth and Planetary Science Letters

300

242

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“…The sample material is vaporized in a focused laser beam and transported with argon gas into the inductively coupled plasma ion source of an ICP-MS. The technique offers several advantages including little or no sample preparation and no solvent interferences, and importantly is able to give information about spatial distributions of elemental profiles [13]. This technique, coupled with scanning tunneling microscopy (STM) and a solution-phase ICP-MS technique allows for a detailed investigation of the coverage of surface-bound molecules.…”

Section: Introductionmentioning

confidence: 99%

Thin films of ruthenium phthalocyanine complexes

et al. 2009

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Four new ruthenium phthalocyanine complexes bearing axial ligands with thioacetate groups that facilitate thin film formation on gold surfaces are presented. STM images and surface coverage data obtained by solution inductively coupled plasma mass spectrometry (ICP-MS) experiments show that peripheral and axial ligand substituents on the complexes have a significant effect on their surface coverage. A laser ablation ICP-MS technique is described here for the first time that provides information about thin films across macro-sized areas. Using the technique, the maximum surface coverage of a ruthenium phthalocyanine complex was found to occur within one minute of gold substrate immersion in the complex-containing solution.

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Laser ablation in analytical chemistry—a review

Cited by 507 publications

References 131 publications

Laser Induced Breakdown Spectroscopy

Laser Induced Breakdown Spectroscopy

Seasonal trace-element and stable-isotope variations in a Chinese speleothem: The potential for high-resolution paleomonsoon reconstruction

Thin films of ruthenium phthalocyanine complexes

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