Formation of carbon nanotubes:<i>In situ</i>optical analysis using laser-induced incandescence and laser-induced fluorescence

Cau, Michèle; Dorval, Nelly; Attal‐Trétout, Brigitte; Cochon, Jean-Lou; Foutel-Richard, Anne; Loiseau, A.; Krüger, Volker; Tsurikov, Michael; Scott, Clayton

doi:10.1103/physrevb.81.165416

Cited by 17 publications

(16 citation statements)

References 46 publications

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“…For example, with the use of CW lasers in this process for the ablation of carbonaceous material from a solid target, the resulting thermal radiation in the plume is analyzed for particle temperature [488,489]. Cau et al [490] reported on the measurement of soot-particle sizes via time-resolved pulsed LII in such a process.…”

Section: Engineered Nanoparticlesmentioning

confidence: 99%

Laser-induced incandescence: Particulate diagnostics for combustion, atmospheric, and industrial applications

Michelsen

Schulz

Smallwood

et al. 2015

Progress in Energy and Combustion Science

320

206

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The understanding of soot formation in combustion processes and the optimization of practical combustion systems require in situ measurement techniques that can provide important characteristics, such as particle concentrations and sizes, under a variety of conditions. Of equal importance are techniques suitable for characterizing soot particles produced from incomplete combustion and emitted into the environment. Additionally, the production of engineered nanoparticles, such as carbon blacks, may benefit from techniques developed. This review discusses considerations for selection of laser and detection characteristics to address application-specific needs. The benefits of using LII for measurements of a range of nanoparticles in the fields mentioned above are demonstrated with some typical examples, covering simple flames, internal-combustion engines, exhaust emissions, the ambient atmosphere, and nanoparticle production. We also remark on less well-known studies employing LII for particles suspended in liquids.An important aspect of the paper is to critically assess the improvement in the understanding of the fundamental physical mechanisms at the nanoscale and the determination of underlying parameters; we also identify further research needs in these contexts. Building on this enhanced capability in describing the underlying complex processes, LII has become a workhorse of particulate measurement in a variety of fields, and its utility continues to be expanding. When coupled with complementary methods, such as light scattering, probe-sampling, molecular-beam techniques, and other nanoparticle instrumentation, new directions for research and applications with LII continue to materialize.

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Section: Engineered Nanoparticlesmentioning

confidence: 99%

Laser-induced incandescence: Particulate diagnostics for combustion, atmospheric, and industrial applications

Michelsen

Schulz

Smallwood

et al. 2015

Progress in Energy and Combustion Science

320

206

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“…Nevertheless, TiRe-LII shows promise for interrogating this morphology, since signal decay rate is roughly proportional to the heat transfer surface area. Cau et al [ 177 ] interpreted TiRe-LII signals from soot and CNTs using a model developed by Krüger et al [ 191 ] for soot, but without accounting for the morphological differences between these two material types. Mitrani and Shneider [ 179 ] presented a simple heat transfer model for MWCNTs, which accounted for their cylindrical shape and allowed for non-uniform temperatures within the nanomaterial.…”

Section: Non-soot Carbonaceous Materialsmentioning

confidence: 99%

Laser-induced incandescence for non-soot nanoparticles: recent trends and current challenges

et al. 2022

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Laser-induced incandescence (LII) is a widely used combustion diagnostic for in situ measurements of soot primary particle sizes and volume fractions in flames, exhaust gases, and the atmosphere. Increasingly, however, it is applied to characterize engineered nanomaterials, driven by the increasing industrial relevance of these materials and the fundamental scientific insights that may be obtained from these measurements. This review describes the state of the art as well as open research challenges and new opportunities that arise from LII measurements on non-soot nanoparticles. An overview of the basic LII model, along with statistical techniques for inferring quantities-of-interest and associated uncertainties is provided, with a review of the application of LII to various classes of materials, including elemental particles, oxide and nitride materials, and non-soot carbonaceous materials, and core–shell particles. The paper concludes with a discussion of combined and complementary diagnostics, and an outlook of future research.

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“…The principles of Laser Induced Fluorescence as applied to C2 detection in low temperature plasmas are described in refs. [26][27][28]. Because signal detection is at a different wavelength from the laser wavelength, PLIF is insensitive to scattered laser light, which can be significant in the arc environment.…”

Section: Planar Laser Induced Fluorescencementioning

confidence: 99%

In situ diagnostics for nanomaterial synthesis in carbon arc plasma

Stratton

Gerakis

Kaganovich

et al. 2018

Plasma Sources Sci. Technol.

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Developments in the recent application of in situ diagnostics to improve understanding of nanomaterial synthesis processes in carbon arc plasma are summarized. These diagnostics measure the plasma conditions in the arc core and the precursor species to nanoparticle formation and the presence and sizes of nanoparticles in the synthesis region surrounding the hot arc core. They provide information that could not be obtained by the ex situ diagnostics used in previous studies of nanomaterial synthesis in arc plasma. The following diagnostics are covered: Optical Emission Spectroscopy, Planar Laser Induced Fluorescence, Laser Induced Incandescence, Fast Frame Imaging, Coherent Rayleigh Brillouin Scattering, and the Nanomaterial Extractor Probe. The diagnostic measurements are consistent with a recently developed two-dimensional fluid model of nanomaterial synthesis in the arc plasma.

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Formation of carbon nanotubes:In situoptical analysis using laser-induced incandescence and laser-induced fluorescence

Cited by 17 publications

References 46 publications

Laser-induced incandescence: Particulate diagnostics for combustion, atmospheric, and industrial applications

Laser-induced incandescence: Particulate diagnostics for combustion, atmospheric, and industrial applications

Laser-induced incandescence for non-soot nanoparticles: recent trends and current challenges

In situ diagnostics for nanomaterial synthesis in carbon arc plasma

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