Relativistic-intensity near-single-cycle light waveforms at kHz repetition rate

Ouillé, Marie; Vernier, Aline; Böhle, Frederik; Bocoum, Maïmouna; Jullien, Aurélie; Lozano, Magali; Rousseau, Jean‐Philippe; Cheng, Ze; Gustas, Dominykas; Blumenstein, Andreas; Simon, Péter; Haessler, Stefan; Faure, Jérôme; Nagy, Tamás; López-Martens, Rodrigo

doi:10.1038/s41377-020-0280-5

Cited by 79 publications

(51 citation statements)

References 50 publications

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“…The laser generates ≈ 10 mJ pulses with central wavelength λ 0 = 800 nm, and full width at half maximum (FWHM) duration of 23 fs. The pulses are then post-compressed in a 2.5 m-long hollow core fiber (HCF) filled with Helium gas 27,28 . Varying the pressure of Helium in the fiber gives control over the spectral bandwidth and therefore over the pulse duration, which was tuned between 3.5 fs and 23 fs in the experiment, see Fig.…”

Section: Methodsmentioning

confidence: 99%

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Demonstration of stable long-term operation of a kilohertz laser-plasma accelerator

Rovige

Huijts

Andriyash

et al. 2020

Phys. Rev. Accel. Beams

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We report on the stable and continuous operation of a kilohertz laser-plasma accelerator. Electron bunches with 2.6 pC charge and 2.5 MeV peak energy were generated via injection and trapping in a downward plasma density ramp. This density transition was produced in a specially designed asymmetrically shocked gas jet. The reproducibility of the electron source was also assessed over a period of a week and found to be satisfactory with similar values of the beam charge and energy. Particle in cell simulations confirm the role of the shock and the density transition in the electron injection mechanism. These results show that the reproducibility and stability of the laser-plasma accelerator are greatly enhanced on the long-term scale when using a robust scheme for density gradient injection.

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Section: Methodsmentioning

confidence: 99%

“…The experiment was conducted using the Salle Noire laser system at LOA [36,37], which provides 10 mJ, 25 fs FWHM laser pulses at kilohertz repetition rate, with a central wavelength λ 0 ¼ 800 nm. The laser pulse is then post-compressed in a helium-filled hollow core fiber (HCF) resulting in a broad spectrum, 4.0 fs pulse.…”

Section: B Experimental Setupmentioning

confidence: 99%

Demonstration of stable long-term operation of a kilohertz laser-plasma accelerator

Rovige

Huijts

Andriyash

et al. 2020

Phys. Rev. Accel. Beams

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show abstract

“…This is to produce electron bunches at higher energy and more separable from the background while keeping a comparable driving laser pulse energy. It has been shown that CEP plays a role in the electron acceleration process in LWFA 28 and in nanoplasma acceleration 29 . Figure 4 demonstrates the generated single bunches using various carrier-envelope phases.…”

Section: Resultsmentioning

confidence: 99%

Towards isolated attosecond electron bunches using ultrashort-pulse laser-solid interactions

Lin

Batson

Nees

et al. 2020

Sci Rep

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We investigate MeV-level attosecond electron bunches from ultrashort-pulse laser-solid interactions through similarities between experimental and simulated electron energy spectra. We show measurements of the bunch duration and temporal structure from particle-in-cell simulations. The experimental observation of such bunches favors specular reflection direction when focusing the laser pulse onto a subwavelength boundary of thick overdense plasmas at grazing incidence. Particle-in-cell simulation further reveals that the attosecond duration is a result of ultra-thin ($$\sim $$ ∼ tenth of a micron) gaps of zero electromagnetic energy density in the modulated reflected radiation, while the bunching (locally peaked electron concentration) comes from the highly-directional electron angular distribution acquired by the electrons in a grazing incidence setup. To isolate a single electron bunch, we perform simulations using 1-cycle laser pulses and analyze the effect of carrier-envelop phase with particle tracking. The duration of the electron bunch can be further decreased by increasing the laser intensity and the focal spot size, while its direction can be changed by tuning the preplasma density gradient.

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“…The HCF technology is the only post-compression technique which reaches the high-energy few-cycle regime with above-mJ, sub-3-cycle pulses (red-shaded area in Figure 9), clearly dominating this field at present. Two of the three best results in this regime were obtained with SF-HCFs (6.1 mJ/ 3.8 fs [153] and 3.5 mJ/3.4 fs [152]) and the third with a long HCF (5 mJ/5 fs [148]). In the terawatt regime the picture is similar: here in addition to the previously mentioned works there is a preliminary result achieved with SF-HCF technology (40 mJ/25 fs [201]).…”

Section: State-of-the-artmentioning

confidence: 95%

“…In the current setup all focusing/recollimating optics are situated in the vacuum/gas chambers and only a large collimated beam at low intensity passes the windows without inducing unwanted nonlinearities. In this way well-controlled CEP-stable 3.5 fs pulses with 3.5 mJ are routinely generated [152]. Recently, an up-scaled version of the system has been commissioned at the Max Born Institute with an overall length of 8.2 m where 14 mJ 50 fs pulses are compressed to 1.5 optical cycles at 3.8 fs duration with an output energy of 6.1 mJ with a peak power of 1.2 TW [153] clearly breaking the TW barrier.…”

Section: Techniques For Further Scalingmentioning

confidence: 99%

High-energy few-cycle pulses: post-compression techniques

Nagy

Simon

Veisz

2020

Advances in Physics: X

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Contemporary ultrafast science requires reliable sources of high-energy few-cycle light pulses. Currently two methods are capable of generating such pulses: post compression of short laser pulses and optical parametric chirped-pulse amplification (OPCPA). Here we give a comprehensive overview on the post-compression technology based on optical Kerr-effect or ionization, with particular emphasis on energy and power scaling. Relevant types of post compression techniques are discussed including free propagation in bulk materials, multiple-plate continuum generation, multi-pass cells, filaments, photonic-crystal fibers, hollow-core fibers and self-compression techniques. We provide a short theoretical overview of the physics as well as an in-depth description of existing experimental realizations of post compression, especially those that can provide few-cycle pulse duration with mJ-scale pulse energy. The achieved experimental performances of these methods are compared in terms of important figures of merit such as pulse energy, pulse duration, peak power and average power. We give some perspectives at the end to emphasize the expected future trends of this technology.

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Relativistic-intensity near-single-cycle light waveforms at kHz repetition rate

Cited by 79 publications

References 50 publications

Demonstration of stable long-term operation of a kilohertz laser-plasma accelerator

Demonstration of stable long-term operation of a kilohertz laser-plasma accelerator

Towards isolated attosecond electron bunches using ultrashort-pulse laser-solid interactions

High-energy few-cycle pulses: post-compression techniques

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