On the structure of quasi-stationary laser ablation fronts in strongly radiating plasmas

Basko, M. M.; Новиков, В. Г.; Grushin, A. S.

doi:10.1063/1.4921334

Cited by 45 publications

(69 citation statements)

References 22 publications

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“…Another reason is departure from the ideal-gas equation of state (EOS) due to multiple temperature-dependent ionization of the target material. These two effects are of major importance for tin (Z = 50) targets at the here considered irradiation intensities 20 . A significant further issue is the non-trivial geometry of the laser-target configuration in our experiments, where a spherical target is irradiated from only one side and an essentially twodimensional (2D) ablation flow develops.…”

Section: Introductionmentioning

confidence: 90%

Power-law scaling of plasma pressure on laser-ablated tin microdroplets

et al. 2018

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The measurement of the propulsion of metallic microdroplets exposed to nanosecond laser pulses provides an elegant method for probing the ablation pressure in dense laser-produced plasma. We present the measurements of the propulsion velocity over three decades in the driving Nd:YAG laser pulse energy, and observe a near-perfect power law dependence. Simulations performed with the RALEF-2D radiation-hydrodynamic code are shown to be in good agreement with the power law above a specific threshold energy. The simulations highlight the importance of radiative losses which significantly modify the power of the pressure scaling. Having found a good agreement between the experiment and the simulations, we investigate the analytic origins of the obtained power law and conclude that none of the available analytic theories is directly applicable for explaining our power exponent.

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Section: Introductionmentioning

confidence: 90%

Power-law scaling of plasma pressure on laser-ablated tin microdroplets

et al. 2018

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“…Nd:YAG-driven light sources have a much higher, near complete laser absorptivity due to the strong increase of the critical plasma electron density n c with decreasing wavelength λ (n c ∝ λ −2 ). The cross section of the here dominant [26] inverse bremsstrahlung absorption mechanism strongly increases with electron density [27,28]. However, the density increase may cause self-absorption of the emitted EUV light, leading to opacity-broadened emission [29][30][31][32].…”

Section: Introductionmentioning

confidence: 99%

Efficient Generation of Extreme Ultraviolet Light From Nd :YAG-Driven Microdroplet-Tin Plasma

et al. 2019

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We experimentally investigate the emission of EUV light from a mass-limited laser-produced plasma over a wide parameter range by varying the diameter of the targeted tin microdroplets and the pulse duration and energy of the 1-μm-wavelength Nd:YAG drive laser. Combining spectroscopic data with absolute measurements of the emission into the 2% bandwidth around 13.5 nm relevant for nanolithographic applications, the plasma's efficiency in radiating EUV light is quantified. All observed dependencies of this radiative efficiency on the experimental parameters are successfully captured in a geometrical model featuring the plasma absorption length as the primary parameter. It is found that laser intensity is the pertinent parameter setting the plasma temperature and the tin-ion charge-state distribution when varying laser pulse energy and duration over almost 2 orders of magnitude. These insights enabled us to obtain a record-high 3.2% conversion efficiency of laser light into 13.5-nm radiation and to identify paths towards obtaining even higher efficiencies with 1-μm solid-state lasers that may rival those of current state-of-the-art CO 2-laser-driven sources.

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“…The time scale of this plasma generation is typically much shorter than the laser pulse. As a result, most of the laser energy is absorbed just before the plasma critical density surface 13 where the plasma electron frequency equals that of the laser light and no further light penetration is possible. This gives the system an effective radius R eff ≥ R 0 , see Fig.…”

Section: Modelmentioning

confidence: 99%

“…In the remainder of this work, we take δ = 0.6 in accordance to Ref. [13]. Furthermore we neglect the small offset energy E 0 , since typically E 0 E (see Ref.…”

Section: Modelmentioning

confidence: 99%

“…Here, we present and experimentally validate an intuitive model describing L2D alignment sensitivity. The model is based on a single parameter: the dimensionless ratio of the laser spot size to the effective size of the droplet target, which we relate to the position of the plasma critical density surface [13][14][15] and sets the typical length scale for the problem. Our model enables the development of straightforward scaling arguments, which in turn enable the minimization of detrimental alignment sensitivity.…”

Section: Introductionmentioning

confidence: 99%

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Laser-to-droplet alignment sensitivity relevant for laser-produced plasma sources of extreme ultraviolet light

Reijers

Kurilovich

Torretti

et al. 2018

Journal of Applied Physics

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We present and experimentally validate a model describing the sensitivity of the tilt angle, expansion and propulsion velocity of a tin micro-droplet irradiated by a 1 µm Nd:YAG laser pulse to its relative alignment. This sensitivity is particularly relevant in industrial plasma sources of extreme ultraviolet light for nanolithographic applications. Our model has but a single parameter: the dimensionless ratio of the laser spot size to the effective size of the droplet, which is related to the position of the plasma critical density surface. Our model enables the development of straightforward scaling arguments in turn enabling precise control the alignment sensitivity.

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On the structure of quasi-stationary laser ablation fronts in strongly radiating plasmas

Cited by 45 publications

References 22 publications

Power-law scaling of plasma pressure on laser-ablated tin microdroplets

Power-law scaling of plasma pressure on laser-ablated tin microdroplets

Efficient Generation of Extreme Ultraviolet Light From Nd :YAG-Driven Microdroplet-Tin Plasma

Laser-to-droplet alignment sensitivity relevant for laser-produced plasma sources of extreme ultraviolet light

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