Your search keyword '"Ta Phuoc K"' showing total 18 results

1. Nonequilibrium warm dense matter investigated with laser-plasma-based XANES down to the femtosecond.

Author

Dorchies F, Ta Phuoc K, and Lecherbourg L

Abstract

The use of laser-plasma-based x-ray sources is discussed, with a view to carrying out time-resolved x-ray absorption spectroscopy measurements, down to the femtosecond timescale. A review of recent experiments performed by our team is presented. They concern the study of the nonequilibrium transition of metals from solid to the warm dense regime, which imposes specific constraints (the sample being destroyed after each shot). Particular attention is paid to the description of experimental devices and methodologies. Two main types of x-ray sources are compared, respectively, based on the emission of a hot plasma, and on the betatron radiation from relativistic electrons accelerated by laser., Competing Interests: The authors have no conflicts to disclose., (© 2023 Author(s).)

Published

2023

2. Controlled acceleration of GeV electron beams in an all-optical plasma waveguide.

Author

Oubrerie K, Leblanc A, Kononenko O, Lahaye R, Andriyash IA, Gautier J, Goddet JP, Martelli L, Tafzi A, Ta Phuoc K, Smartsev S, and Thaury C

Abstract

Laser-plasma accelerators (LPAs) produce electric fields of the order of 100 GV m -1 , more than 1000 times larger than those produced by radio-frequency accelerators. These uniquely strong fields make LPAs a promising path to generate electron beams beyond the TeV, an important goal in high-energy physics. Yet, large electric fields are of little benefit if they are not maintained over a long distance. It is therefore of the utmost importance to guide the ultra-intense laser pulse that drives the accelerator. Reaching very high energies is equally useless if the properties of the electron beam change completely from shot to shot, due to the intrinsic lack of stability of the injection process. State-of-the-art laser-plasma accelerators can already address guiding and control challenges separately by tweaking the plasma structures. However, the production of beams that are simultaneously high quality and high energy has yet to be demonstrated. This paper presents a novel experiment, coupling laser-plasma waveguides and controlled injection techniques, facilitating the reliable and efficient acceleration of high-quality electron beams up to 1.1 GeV, from a 50 TW-class laser., (© 2022. The Author(s).)

Published

2022

3. Femtosecond Resolution of the Nonballistic Electron Energy Transport in Warm Dense Copper.

Author

Grolleau A, Dorchies F, Jourdain N, Ta Phuoc K, Gautier J, Mahieu B, Renaudin P, Recoules V, Martinez P, and Lecherbourg L

Abstract

The ultrafast electron energy transport is investigated in laser-heated warm dense copper in a high flux regime (2.5±0.7×10^{13}  W/cm^{2} absorbed). The dynamics of the electron temperature is retrieved from femtosecond time-resolved x-ray absorption near-edge spectroscopy near the Cu L3 edge. A characteristic time of ∼1  ps is observed for the increase in the average temperature in a 100 nm thick sample. Data are well reproduced by two-temperature hydrodynamic simulations, which support energy transport dominated by thermal conduction rather than ballistic electrons.

Published

2021

4. Energy-Chirp Compensation in a Laser Wakefield Accelerator.

Author

Döpp A, Thaury C, Guillaume E, Massimo F, Lifschitz A, Andriyash I, Goddet JP, Tazfi A, Ta Phuoc K, and Malka V

Abstract

The energy spread in laser wakefield accelerators is primarily limited by the energy chirp introduced during the injection and acceleration processes. Here, we propose the use of longitudinal density tailoring to reduce the beam chirp at the end of the accelerator. Experimental data sustained by quasi-3D particle-in-cell simulations show that broadband electron beams can be converted to quasimonoenergetic beams of ≤10% energy spread while maintaining a high charge of more than 120 pC. In the linear and quasilinear regimes of wakefield acceleration, the method could provide even lower, subpercent level, energy spread.

Published

2018

5. Probing warm dense matter using femtosecond X-ray absorption spectroscopy with a laser-produced betatron source.

Author

Mahieu B, Jourdain N, Ta Phuoc K, Dorchies F, Goddet JP, Lifschitz A, Renaudin P, and Lecherbourg L

Abstract

Exploring and understanding ultrafast processes at the atomic level is a scientific challenge. Femtosecond X-ray absorption spectroscopy (XAS) arises as an essential experimental probing method, as it can simultaneously reveal both electronic and atomic structures, and thus potentially unravel their nonequilibrium dynamic interplay which is at the origin of most of the ultrafast mechanisms. However, despite considerable efforts, there is still no femtosecond X-ray source suitable for routine experiments. Here we show that betatron radiation from relativistic laser-plasma interaction combines ideal features for femtosecond XAS. It has been used to investigate the nonequilibrium dynamics of a copper sample brought at extreme conditions of temperature and pressure by a femtosecond laser pulse. We measured a rise-time of the electron temperature below 100 fs. This experiment demonstrates the great potential of the table-top betatron source which makes possible the investigation of unexplored ultrafast processes in manifold fields of research.

Published

2018

6. High-Brilliance Betatron γ-Ray Source Powered by Laser-Accelerated Electrons.

Author

Ferri J, Corde S, Döpp A, Lifschitz A, Doche A, Thaury C, Ta Phuoc K, Mahieu B, Andriyash IA, Malka V, and Davoine X

Abstract

Recent progress in laser-driven plasma acceleration now enables the acceleration of electrons to several gigaelectronvolts. Taking advantage of these novel accelerators, ultrashort, compact, and spatially coherent x-ray sources called betatron radiation have been developed and applied to high-resolution imaging. However, the scope of the betatron sources is limited by a low energy efficiency and a photon energy in the 10 s of kiloelectronvolt range, which for example prohibits the use of these sources for probing dense matter. Here, based on three-dimensional particle-in-cell simulations, we propose an original hybrid scheme that combines a low-density laser-driven plasma accelerator with a high-density beam-driven plasma radiator, thereby considerably increasing the photon energy and the radiated energy of the betatron source. The energy efficiency is also greatly improved, with about 1% of the laser energy transferred to the radiation, and the γ-ray photon energy exceeds the megaelectronvolt range when using a 15 J laser pulse. This high-brilliance hybrid betatron source opens the way to a wide range of applications requiring MeV photons, such as the production of medical isotopes with photonuclear reactions, radiography of dense objects in the defense or industrial domains, and imaging in nuclear physics.

Published

2018

7. Publisher Correction: Control of laser plasma accelerated electrons for light sources.

Author

André T, Andriyash IA, Loulergue A, Labat M, Roussel E, Ghaith A, Khojoyan M, Thaury C, Valléau M, Briquez F, Marteau F, Tavakoli K, N'Gotta P, Dietrich Y, Lambert G, Malka V, Benabderrahmane C, Vétéran J, Chapuis L, El Ajjouri T, Sebdaoui M, Hubert N, Marcouillé O, Berteaud P, Leclercq N, El Ajjouri M, Rommeluère P, Bouvet F, Duval J-, Kitegi C, Blache F, Mahieu B, Corde S, Gautier J, Ta Phuoc K, Goddet JP, Lestrade A, Herbeaux C, Évain C, Szwaj C, Bielawski S, Tafzi A, Rousseau P, Smartsev S, Polack F, Dennetière D, Bourassin-Bouchet C, De Oliveira C, and Couprie M-

Abstract

The original version of this Article contained an error in the last sentence of the first paragraph of the Introduction and incorrectly read 'A proper electron beam control is one of the main challenges towards the Graal of developing a compact alternative of X-ray free-electron lasers by coupling LWFA gigaelectron-volts per centimetre acceleration gradient with undulators in the amplification regime in equation 11, nx(n-β) x β: n the two times and beta the two times should be bold since they are vectorsin Eq. 12, β should be bold as well.' The correct version is 'A proper electron beam control is one of the main challenges towards the Graal of developing a compact alternative of X-ray free-electron lasers by coupling LWFA gigaelectron-volts per centimetre acceleration gradient with undulators in the amplification regime.'This has been corrected in both the PDF and HTML versions of the Article.

Published

2018

8. Control of laser plasma accelerated electrons for light sources.

Author

André T, Andriyash IA, Loulergue A, Labat M, Roussel E, Ghaith A, Khojoyan M, Thaury C, Valléau M, Briquez F, Marteau F, Tavakoli K, N'Gotta P, Dietrich Y, Lambert G, Malka V, Benabderrahmane C, Vétéran J, Chapuis L, El Ajjouri T, Sebdaoui M, Hubert N, Marcouillé O, Berteaud P, Leclercq N, El Ajjouri M, Rommeluère P, Bouvet F, Duval J-, Kitegi C, Blache F, Mahieu B, Corde S, Gautier J, Ta Phuoc K, Goddet JP, Lestrade A, Herbeaux C, Évain C, Szwaj C, Bielawski S, Tafzi A, Rousseau P, Smartsev S, Polack F, Dennetière D, Bourassin-Bouchet C, De Oliveira C, and Couprie ME

Abstract

With gigaelectron-volts per centimetre energy gains and femtosecond electron beams, laser wakefield acceleration (LWFA) is a promising candidate for applications, such as ultrafast electron diffraction, multistaged colliders and radiation sources (betatron, compton, undulator, free electron laser). However, for some of these applications, the beam performance, for example, energy spread, divergence and shot-to-shot fluctuations, need a drastic improvement. Here, we show that, using a dedicated transport line, we can mitigate these initial weaknesses. We demonstrate that we can manipulate the beam longitudinal and transverse phase-space of the presently available LWFA beams. Indeed, we separately correct orbit mis-steerings and minimise dispersion thanks to specially designed variable strength quadrupoles, and select the useful energy range passing through a slit in a magnetic chicane. Therefore, this matched electron beam leads to the successful observation of undulator synchrotron radiation after an 8 m transport path. These results pave the way to applications demanding in terms of beam quality.

Published

2018

9. Stable femtosecond X-rays with tunable polarization from a laser-driven accelerator.

Author

Döpp A, Mahieu B, Lifschitz A, Thaury C, Doche A, Guillaume E, Grittani G, Lundh O, Hansson M, Gautier J, Kozlova M, Goddet JP, Rousseau P, Tafzi A, Malka V, Rousse A, Corde S, and Ta Phuoc K

Abstract

Technology based on high-peak-power lasers has the potential to provide compact and intense radiation sources for a wide range of innovative applications. In particular, electrons that are accelerated in the wakefield of an intense laser pulse oscillate around the propagation axis and emit X-rays. This betatron source, which essentially reproduces the principle of a synchrotron at the millimeter scale, provides bright radiation with femtosecond duration and high spatial coherence. However, despite its unique features, the usability of the betatron source has been constrained by its poor control and stability. In this article, we demonstrate the reliable production of X-ray beams with tunable polarization. Using ionization-induced injection in a gas mixture, the orbits of the relativistic electrons emitting the radiation are reproducible and controlled. We observe that both the signal and beam profile fluctuations are significantly reduced and that the beam pointing varies by less than a tenth of the beam divergence. The polarization ratio reaches 80%, and the polarization axis can easily be rotated. We anticipate a broad impact of the source, as its unprecedented performance opens the way for new applications., Competing Interests: The authors declare no conflict of interest.

Published

2017

10. 3D printing of gas jet nozzles for laser-plasma accelerators.

Author

Döpp A, Guillaume E, Thaury C, Gautier J, Ta Phuoc K, and Malka V

Abstract

Recent results on laser wakefield acceleration in tailored plasma channels have underlined the importance of controlling the density profile of the gas target. In particular, it was reported that the appropriate density tailoring can result in improved injection, acceleration, and collimation of laser-accelerated electron beams. To achieve such profiles, innovative target designs are required. For this purpose, we have reviewed the usage of additive layer manufacturing, commonly known as 3D printing, in order to produce gas jet nozzles. Notably we have compared the performance of two industry standard techniques, namely, selective laser sintering (SLS) and stereolithography (SLA). Furthermore we have used the common fused deposition modeling to reproduce basic gas jet designs and used SLA and SLS for more sophisticated nozzle designs. The nozzles are characterized interferometrically and used for electron acceleration experiments with the Salle Jaune terawatt laser at Laboratoire d'Optique Appliquée.

Published

2016

11. Effect of experimental laser imperfections on laser wakefield acceleration and betatron source.

Author

Ferri J, Davoine X, Fourmaux S, Kieffer JC, Corde S, Ta Phuoc K, and Lifschitz A

Abstract

Laser pulses in current ultra-short TW systems are far from being ideal Gaussian beams. The influence of the presence of non-Gaussian features of the laser pulse is investigated here from experiments and 3D Particle-in-Cell simulations. Both the experimental intensity distribution and wavefront are used as input in the simulations. It is shown that a quantitative agreement between experimental data and simulations requires to use realistic pulse features. Moreover, some trends found in the experiments, such as the growing of the X-ray signal with the plasma length, can only be retrieved in simulations with realistic pulses. The performances on the electron acceleration and the synchrotron X-ray emission are strongly degraded by these non-Gaussian features, even keeping constant the total laser energy. A drop on the X-ray photon number by one order of magnitude was found. This clearly put forward the limitation of using a Gaussian beam in the simulations.

Published

2016

12. Shock assisted ionization injection in laser-plasma accelerators.

Author

Thaury C, Guillaume E, Lifschitz A, Ta Phuoc K, Hansson M, Grittani G, Gautier J, Goddet JP, Tafzi A, Lundh O, and Malka V

Abstract

Ionization injection is a simple and efficient method to trap an electron beam in a laser plasma accelerator. Yet, because of a long injection length, this injection technique leads generally to the production of large energy spread electron beams. Here, we propose to use a shock front transition to localize the injection. Experimental results show that the energy spread can be reduced down to 10 MeV and that the beam energy can be tuned by varying the position of the shock. This simple technique leads to very stable and reliable injection even for modest laser energy. It should therefore become a unique tool for the development of laser-plasma accelerators.

Published

2015

13. Electron Rephasing in a Laser-Wakefield Accelerator.

Author

Guillaume E, Döpp A, Thaury C, Ta Phuoc K, Lifschitz A, Grittani G, Goddet JP, Tafzi A, Chou SW, Veisz L, and Malka V

Abstract

An important limit for energy gain in laser-plasma wakefield accelerators is the dephasing length, after which the electron beam reaches the decelerating region of the wakefield and starts to decelerate. Here, we propose to manipulate the phase of the electron beam in the wakefield, in order to bring the beam back into the accelerating region, hence increasing the final beam energy. This rephasing is operated by placing an upward density step in the beam path. In a first experiment, we demonstrate the principle of this technique using a large energy spread electron beam. Then, we show that it can be used to increase the energy of monoenergetic electron beams by more than 50%.

Published

2015

14. Demonstration of relativistic electron beam focusing by a laser-plasma lens.

Author

Thaury C, Guillaume E, Döpp A, Lehe R, Lifschitz A, Ta Phuoc K, Gautier J, Goddet JP, Tafzi A, Flacco A, Tissandier F, Sebban S, Rousse A, and Malka V

Abstract

Laser-plasma technology promises a drastic reduction of the size of high-energy electron accelerators. It could make free-electron lasers available to a broad scientific community and push further the limits of electron accelerators for high-energy physics. Furthermore, the unique femtosecond nature of the source makes it a promising tool for the study of ultrafast phenomena. However, applications are hindered by the lack of suitable lens to transport this kind of high-current electron beams mainly due to their divergence. Here we show that this issue can be solved by using a laser-plasma lens in which the field gradients are five order of magnitude larger than in conventional optics. We demonstrate a reduction of the divergence by nearly a factor of three, which should allow for an efficient coupling of the beam with a conventional beam transport line.

Published

2015

15. Angular-momentum evolution in laser-plasma accelerators.

Author

Thaury C, Guillaume E, Corde S, Lehe R, Le Bouteiller M, Ta Phuoc K, Davoine X, Rax JM, Rousse A, and Malka V

Abstract

The transverse properties of an electron beam are characterized by two quantities, the emittance which indicates the electron beam extent in the phase space and the angular momentum which allows for nonplanar electron trajectories. Whereas the emittance of electron beams produced in a laser-plasma accelerator has been measured in several experiments, their angular momentum has been scarcely studied. It was demonstrated that electrons in a laser-plasma accelerator carry some angular momentum, but its origin was not established. Here we identify one source of angular-momentum growth and we present experimental results showing that the angular-momentum content evolves during the acceleration.

Published

2013

16. Observation of longitudinal and transverse self-injections in laser-plasma accelerators.

Author

Corde S, Thaury C, Lifschitz A, Lambert G, Ta Phuoc K, Davoine X, Lehe R, Douillet D, Rousse A, and Malka V

Abstract

Laser-plasma accelerators can produce high-quality electron beams, up to giga electronvolts in energy, from a centimetre scale device. The properties of the electron beams and the accelerator stability are largely determined by the injection stage of electrons into the accelerator. The simplest mechanism of injection is self-injection, in which the wakefield is strong enough to trap cold plasma electrons into the laser wake. The main drawback of this method is its lack of shot-to-shot stability. Here we present experimental and numerical results that demonstrate the existence of two different self-injection mechanisms. Transverse self-injection is shown to lead to low stability and poor-quality electron beams, because of a strong dependence on the intensity profile of the laser pulse. In contrast, longitudinal injection, which is unambiguously observed for the first time, is shown to lead to much more stable acceleration and higher-quality electron beams.

Published

2013

17. Coherence-based transverse measurement of synchrotron x-ray radiation from relativistic laser-plasma interaction and laser-accelerated electrons.

Author

Shah RC, Albert F, Ta Phuoc K, Shevchenko O, Boschetto D, Pukhov A, Kiselev S, Burgy F, Rousseau JP, and Rousse A

Abstract

We observe Fresnel edge diffraction of the x-ray beam generated by the relativistic interaction of a high-intensity laser pulse with He gas. The observed diffraction at center energy 4.5 keV agrees with Gaussian incoherent source profile of full-width-half-maximum (FWHM) < 8 microm. Analysis indicates this corresponds to an upper limit on the transverse profile of laser-accelerated electrons within the plasma in agreement with three-dimensional, particle-in-cell results (FWHM = 4 microm).

Published

2006

18. X-ray radiation from nonlinear Thomson scattering of an intense femtosecond laser on relativistic electrons in a helium plasma.

Author

Ta Phuoc K, Rousse A, Pittman M, Rousseau JP, Malka V, Fritzler S, Umstadter D, and Hulin D

Abstract

We have generated x-ray radiation from the nonlinear Thomson scattering of a 30 fs/1.5 J laser beam on plasma electrons. A collimated x-ray radiation with a broad continuous spectrum peaked at 0.15 keV with a significant tail up to 2 keV has been observed. These characteristics are found to depend strongly on the laser strength parameter a(0). This radiative process is dominant for a(0) greater than unity at which point the relativistic scattering of the laser light originates from MeV energy electrons inside the plasma.

Published

2003