Effect of Plasma Scale Length on Multi-MeV Proton Production by Intense Laser Pulses

Mackinnon, A. J.; Borghesi, M.; Hatchett, S.; Key, M. H.; Patel, P. K.; Campbell, H. D.; Schiavi, A.; Snavely, R.; Wilks, S. C.; Willi, O.

doi:10.1103/physrevlett.86.1769

Cited by 254 publications

(139 citation statements)

References 15 publications

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“…A comparison between cases with and without a prepulse shows a variation in ion energies of a factor of 2-4. 7 Numerical simulations also suggested approximately two times reduction in velocity when a smooth initial ion density profile is considered. 5 Recently we demonstrated a much larger reduction factor of 30 in ion energy from a laser-produced Sn plasma by introducing a low energy prepulse.…”

Section: Introductionmentioning

confidence: 96%

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Investigation of the interaction of a laser pulse with a preformed Gaussian Sn plume for an extreme ultraviolet lithography source

Tao

Tillack

Harilal

et al. 2007

Journal of Applied Physics

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The interaction of a laser pulse with a Sn preplasma formed by a low energy prepulse was investigated for an extreme ultraviolet ͑EUV͒ lithography light source. A much lower ion kinetic energy and nearly the same conversion efficiency from laser to in-band ͑2% bandwidth͒ 13.5 nm EUV light were simultaneously observed as compared with those from the direct interaction with a solid surface. The reason comes from the interaction of the laser pulse with a smooth preplume induced by the prepulse. The density profile of the preplume was measured with time-resolved shadowgraphy and could be fitted with a Gaussian function. The energy of the ions located at the flux peak E p scales with the length of the preplume l s as E p ϰ 1/l s . Laser absorption in the low-density preplume and ion acceleration during plasma expansion are discussed. This result provides a general way to control particle energy from a laser plasma interaction.

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Section: Introductionmentioning

confidence: 96%

“…It has been shown that both the maximum energy and angular distribution depend on the level of the prepulse. 7,8 Ion acceleration is more efficient with a short initial scale length. A comparison between cases with and without a prepulse shows a variation in ion energies of a factor of 2-4.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the interaction of a laser pulse with a preformed Gaussian Sn plume for an extreme ultraviolet lithography source

Tao

Tillack

Harilal

et al. 2007

Journal of Applied Physics

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“…Some further considerations can be made regarding the role played by the prepulse. The observation of energetic protons in both experiments implies that the prepulse was not capable of eroding the total target thickness before the arrival of the main CPA on target [21]. Indeed, 2D hydrodynamic simulations using the code POLLUX [22] indicate that ablation by a prepulse with the experimental parameters is not sufficient to disrupt the rear surface of foils thicker than 1 m. A combination of the hydrosimulation results and interferometric measurements also provides information on the plasma conditions at the front surface immediately before the CPA interaction: the preplasma has a gradient of a few m scale length at the critical density surface, which is located a few m in front of the solid density target.…”

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confidence: 99%

Plasma Jets Driven by Ultraintense-Laser Interaction with Thin Foils

Kar

Borghesi

Bulanov³

et al. 2008

Phys. Rev. Lett.

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“…7,8 An induced density gradient can drastically reduce the effectiveness of the TNSA mechanism. 9 The thinner the target, the more sensitive it is to such prepulses. For a given peak laser intensity, the optimum target thickness is thus related to the laser temporal contrast, defined as the ratio between the intensity of the main pulse to that of the pedestal or prepulse.…”

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confidence: 99%

Enhanced proton beams from ultrathin targets driven by high contrast laser pulses

Neely

Foster

Robinson

et al. 2006

Applied Physics Letters

228

154

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The generation of proton beams from ultrathin targets, down to 20 nm in thickness, driven with ultrahigh contrast laser pulses is explored. the conversion efficiency from laser energy into protons increases as the foil thickness is decreased, with good beam quality and high efficiencies of 1% being achieved, for protons with kinetic energy exceeding 0.9 MeV, for 100 nm thick aluminum foils at intensities of 10(19) W/cm(2) with 33 fs, 0.3 J pulses. To minimize amplified spontaneous emission (ASE) induced effects disrupting the acceleration mechanism, exceptional laser to ASE intensity contrasts of up to 1010 are achieved by introducing a plasma mirror to the high contrast 10 Hz multiterawatt laser at the Lund Laser Centre. It is shown that for a given laser energy on target, regimes of higher laser-to-proton energy conversion efficiency. can be accessed with increasing contrast. The increasing efficiency as the target thickness decreases is closely correlated to an increasing proton temperature. (c) 2006 American Institute of Physics

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Effect of Plasma Scale Length on Multi-MeV Proton Production by Intense Laser Pulses

Cited by 254 publications

References 15 publications

Investigation of the interaction of a laser pulse with a preformed Gaussian Sn plume for an extreme ultraviolet lithography source

Investigation of the interaction of a laser pulse with a preformed Gaussian Sn plume for an extreme ultraviolet lithography source

Plasma Jets Driven by Ultraintense-Laser Interaction with Thin Foils

Enhanced proton beams from ultrathin targets driven by high contrast laser pulses

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