Influence of spot size on propagation dynamics of laser-produced tin plasma

Harilal, S. S.

doi:10.1063/1.2822450

Cited by 85 publications

(35 citation statements)

References 37 publications

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“…Compared to vacuum, the interaction of LPP with a background gas becomes complicated because of involvement of new processes, such as reduction in ablation, formation of shock waves and clustering, plume splitting and sharpening, deceleration and confinement of ablated species, thermalization of the ablated species, diffusion, etc. [19][20][21][22][23][24][25] Background pressure levels also play an important role on the morphology of the laser irradiated region and evolution of LPP. 8 In nanosecond laser ablation, plasma shielding is one of the most important factors that control the ablation as well as the emission, and the nature and pressure of ambient gas have a definite role in controlling the shielding effect.…”

Section: Introductionmentioning

confidence: 99%

Emission features and expansion dynamics of nanosecond laser ablation plumes at different ambient pressures

Farid

Harilal²,

Ding

et al. 2014

Journal of Applied Physics

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180

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Section: Introductionmentioning

confidence: 99%

Emission features and expansion dynamics of nanosecond laser ablation plumes at different ambient pressures

Farid

Harilal²,

Ding

et al. 2014

Journal of Applied Physics

Self Cite

180

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“…It can play a crucial role in the development of extreme ultraviolet lithography source, thin film deposition, synthesis of nanoparticles, metallic atomic beam source for accelerators, and probing neutral atomic beam in plasma environment (Chrisey & Hubler, 1994;Geohegan et al, 1998;Doria et al, 2004;Fazio et al, 2009;Hoffman, 2009;Huber et al, 2005;Masnavi et al, 2006;Nardi et al, 2009;Sizyuk et al, 2007;Wolowski et al, 2007;Wang et al, 2007). Several attempts have been made to optimize the expanding laser produced plasma plume by varying experimental factors like, ambient gas, focal spot size, laser pulse width, irradiance, and wavelength of ablating laser (Key et al, 1983;Bulgakova et al, 2000;Amoruso et al, 2003;Harilal, 2007;Beilis, 2007;Laska et al, 2008;Rafique et al, 2008). General observation is that the lateral velocity of the plume species increases with the increase in the laser fluence.…”

Section: Introductionmentioning

confidence: 99%

Influence of laser beam intensity profile on propagation dynamics of laser-blow-off plasma plume

et al. 2010

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Effect of intensity profile of the ablating laser on the dynamics of laser-blow-off (LBO) plume has been studied by fast imaging technique. This work emphasizes the geometrical aspect of the LBO plume, which is an important parameter for various applications. Visualization of the expanding plume reveals that geometrical shape and directionality (divergence) of the plume are highly dependent on the laser intensity profile. Present results demonstrate that the Gaussian profile laser produces a well-collimated, low divergence plasma plume as compared to the plume formed by a top-hat profile laser. The sequence of film removal processes is invoked to explain the role of energy density profile of the ablating laser in LBO mechanism.

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“…The laser pulse length determined the laser intensity, and affected the size and shape of the resulting plasma. 29,30 The BAS-SR IP was chosen because of the protective mylar film on the surface of the plate. The mylar film performed as a filter for other radiation species produced on ablation of the tin target.…”

Section: A Euv and Imaging Plate Datamentioning

confidence: 99%

High-space resolution imaging plate analysis of extreme ultraviolet (EUV) light from tin laser-produced plasmas

Musgrave

Takehiro

Ugomori

et al. 2017

Review of Scientific Instruments

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With the advent of high volume manufacturing capabilities by extreme ultraviolet lithography, constant improvements in light source design and cost-efficiency are required. Currently, light intensity and conversion efficiency (CE) measurments are obtained by charged couple devices, faraday cups etc, but also phoshpor imaging plates (IPs) (BaFBr:Eu). IPs are sensitive to light and high-energy species, which is ideal for studying extreme ultraviolet (EUV) light from laser produced plasmas (LPPs). In this work, we used IPs to observe a large angular distribution (10°-90°). We ablated a tin target by high-energy lasers (1064 nm Nd:YAG, 1010 and 1011 W/cm2) to generate the EUV light. The europium ions in the IP were trapped in a higher energy state from exposure to EUV light and high-energy species. The light intensity was angular dependent; therefore excitation of the IP depends on the angle, and so highly informative about the LPP. We obtained high-space resolution (345 μm, 0.2°) angular distribution and grazing spectrometer (5-20 nm grate) data simultaneously at different target to IP distances (103 mm and 200 mm). Two laser systems and IP types (BAS-TR and BAS-SR) were also compared. The cosine fitting values from the IP data were used to calculate the CE to be 1.6% (SD ± 0.2) at 13.5 nm 2% bandwidth. Finally, a practical assessment of IPs and a damage issue are disclosed.

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Influence of spot size on propagation dynamics of laser-produced tin plasma

Cited by 85 publications

References 37 publications

Emission features and expansion dynamics of nanosecond laser ablation plumes at different ambient pressures

Emission features and expansion dynamics of nanosecond laser ablation plumes at different ambient pressures

Influence of laser beam intensity profile on propagation dynamics of laser-blow-off plasma plume

High-space resolution imaging plate analysis of extreme ultraviolet (EUV) light from tin laser-produced plasmas

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