Experimental investigation of ultraviolet laser induced plasma density and temperature evolution in air

Thiyagarajan, M.; Scharer, J.E.

doi:10.1063/1.2952540

Cited by 77 publications

(41 citation statements)

References 22 publications

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“…An order of magnitude decrease in the electron temperature of Xe plasma is observed within the first 250 ps after the plasma formation. Tracking such rapid dynamics was made possible in our measurements because the temporal resolution is increased by several orders of magnitude compared to the previous nanosecond measurements [29,30,33,34]. The e> [35] , and provide a complement to the h lower values of p I is manifest in the intensity evolution of the FWM signal generated in the micro-plasma.…”

Section: Methodsmentioning

confidence: 65%

“…However, these spectroscopic techniques have only been demonstrated for relatively long time scales of >10 ns. The electron temperature can also be determined by measuring the expansion velocity of the shock wave generated by the plasma [33,34]. Measurements of plasmas produced by ns pulses have been made in air using a cw probe in which the temporal resolution was limited by the gating of the CCD detection to the nanosecond timescale [33,34].…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of strong-field laser-induced microplasma formation in noble gases

et al. 2010

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The ultrafast dynamics of micro-plasmas generated by a femtosecond laser pulses in noble gases has been investigated using four-wave mixing (FWM). The time dependence of the FWM signal is observed to reach higher intensity levels faster for Xe, with progressively lower scattering intensity and longer time dynamics for the noble gas series Xe, Kr, Ar, Ne and He. The temporal dynamics is interpreted in terms of a tunnel ionization and impact cooling mechanism. A formalism to interpret the observed phenomena is presented here with comparison to the measured laser intensity and gas pressure trends.

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Section: Methodsmentioning

confidence: 65%

Section: Introductionmentioning

confidence: 99%

Dynamics of strong-field laser-induced microplasma formation in noble gases

et al. 2010

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“…The ratio for intensity of two lines of the same species of ionization stage Z in the emission spectrum of the target ablated b laser is expressed as: where I 1 is the line intensity from the k-i transition (arbitrary unit), I 2 is that from the nm transition (arbitrary unit), is the wavelength from the k-i transition (nm), is the wavelength from the n-m transition (nm), is the transition probability from the k-i transition (s -1 ) , is the transition probability from the n-m transition (s -1 ), is the statistical weight of the k state, is the statistical weight of the n state, is the energy of the k state (eV), is the energy of the n state (eV), k B is the Boltzmann constant 1.38x10 -23 J.K -1 , and T e is the electron temperature (eV). From equation (1) we can find the electron temperature T e by comparison of two spectral lines in the emission spectrum [10]. The aim of this research is to estimate electron temperature T e of plasma produced by Nd:YAG pulsed laser of Al element which can be used in many application such as electroptics devices and semiconductors alloys.…”

Section: Introductionmentioning

confidence: 99%

“…By increasing the fluence over the ablation threshold, the saturation of the produced plasma density allows the increase of the ions and electrons temperatures [7]. Because of the transient features of the plasma created by LIP, optical emission spectroscopy (OES) technique with time and space resolution is especially used to obtain information about the behavior of the created plasma species in space and time as well as the dynamics of the plasma evolution [8][9][10]. The ratio for intensity of two lines of the same species of ionization stage Z in the emission spectrum of the target ablated b laser is expressed as: where I 1 is the line intensity from the k-i transition (arbitrary unit), I 2 is that from the nm transition (arbitrary unit), is the wavelength from the k-i transition (nm), is the wavelength from the n-m transition (nm), is the transition probability from the k-i transition (s -1 ) , is the transition probability from the n-m transition (s -1 ), is the statistical weight of the k state, is the statistical weight of the n state, is the energy of the k state (eV), is the energy of the n state (eV), k B is the Boltzmann constant 1.38x10 -23 J.K -1 , and T e is the electron temperature (eV).…”

Section: Introductionmentioning

confidence: 99%

Measurement the Spectroscopic Temperature of Electron in Aluminum Laser Induced Plasma

Abdulameer¹

2017

JNUS

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In this research, optical emission spectroscopic studies have been carried out in Aluminum plasma generated using 1064nm, 10ns pulses from Nd:YAG laser. Temperature was estimated from the analysis of spectral data. The temperature values measurements have been performed by the comparison of two selected spectral lines of the radiation emitted by laser induced plasma of Al using singly ionized Al atom and neutral lines. An initial temperature of 2.6 eV was measured. The relation between electron temperature and laser pulse energy in the laser-generated Al plasma have been analyzed. The electron temperatures values are found to increase from 2.6 eV to 2.8 eV then to 2.9 eV as increasing laser pulse energy.

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“…The crucial issue involved in efficient coupling of optical energy is the interaction of high power laser beams with materials, which is an intriguing field of research owing to the nonlinear optical properties coming to the fore during laser-matter interaction. In the study of laser induced shockwaves in ambient conditions and in under dense plasmas, the existing theoretical and experimental reports mostly consider the SWs emanate from a single point source [6][7][8] and neglects the self-focusing of laser pulses interacting with the plasma. To address this issue, we present our results from the SHW imaging technique revealing the dynamics of LISW and hot core plasma (HCP) from LPP in air generated with 7 ns laser pulses which gives the full spatial information of the evolution of the position of SW fronts and expansion of the hot gas.…”

Section: Introductionmentioning

confidence: 99%

Shockwave and cavitation bubble dynamics of atmospheric air

Leela

Bagchi

Tewari

et al. 2013

EPJ Web of Conferences

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Abstract. The generation and evolution of laser induced shock waves (SWs) and the hot core plasma (HCP) created by focusing 7 ns, 532 nm laser pulses in ambient air is studied using time resolved shadowgraphic imaging technique. The dynamics of rapidly expanding plasma releasing SWs into the ambient atmosphere were studied for time delays ranging from nanoseconds to milliseconds with ns temporal resolution. The SW is observed to get detached from expanding HCP at around 3 s. Though the SWs were found to expand spherically following the Sedov-Taylor theory, the rapidly expanding HCP shows asymmetric expansion during both the expansion and cooling phase similar to that of inertial cavitation bubble (CB) dynamics. The asymmetric expansion of HCP leads to oscillation of the plasma boundary, eventually leading to collapse by forming vortices formed by the interaction of ambient air.

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Experimental investigation of ultraviolet laser induced plasma density and temperature evolution in air

Cited by 77 publications

References 22 publications

Dynamics of strong-field laser-induced microplasma formation in noble gases

Dynamics of strong-field laser-induced microplasma formation in noble gases

Measurement the Spectroscopic Temperature of Electron in Aluminum Laser Induced Plasma

Shockwave and cavitation bubble dynamics of atmospheric air

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