Your search keyword '"Sebdaoui M"' showing total 14 results

1. FAB10: a user-oriented bandwidth-tunable extreme ultraviolet lightsource for investigations of femtosecond to attosecond dynamics in gas and condensed phases

Author

Bresteau, D., Spezzani, C., Tcherbakoff, O., Hergott, J.-F., Lepetit, F., D’Oliveira, P., Salières, P., Géneaux, R., Luttmann, M., Vadillo-Torre, I., Lenfant, J., Weber, S. J., Dehlinger, M., Meltchakov, E., Delmotte, F., Bourassin-Bouchet, C., Im, J., Chen, Z., Caillaux, J., Zhang, J., Marsi, M., Barreau, L., Poisson, L., Dowek, D., Fanciulli, M., Heckmann, O., Richter, M. C., Hricovini, K., Sebdaoui, M., Dennetiere, D., Polack, F., and Ruchon, T.

Published

2023

2. Variable high gradient permanent magnet quadrupole (QUAPEVA)

Author

Marteau, F ., N'gotta, P., Benabderrahmane, C., Ghaith, A., Valléau, M., Loulergue, A., Vétéran, J., Sebdaoui, M., André, T., Bec, G. Le, Chavanne, J., Vallerand, C., Oumbarek, D., Cosson, O., Forest, F., Jivkov, P., Lancelot, J. L., and Couprie, M. E.

Subjects

Physics - Accelerator Physics

Abstract

High gradient quadrupoles are necessary for different applications such as laser plasma acceleration, colliders, and diffraction limited light sources. Permanent magnet quadrupoles provide a higher field strength and compactness than conventional electro-magnets. An original design of permanent magnet based quadrupole (so-called "QUAPEVA"), composed of a Halbach ring placed in the center with a bore radius of 6 mm and surrounded by four permanent magnet cylinders capable of providing a gradient of 210 T/m, is presented. The design of the QUAPEVAs, including magnetic simulation modeling, and mechanical issues are reported. Magnetic measurements of seven systems of different lengths are presented and confirmed the theoretical expectations. The variation of the magnetic center while changing the gradient strength is +/- 10 micrometer. A triplet of three QUAPEVA magnets are used to focus a beam with large energy spread and high divergence that is generated by Laser Plasma Acceleration source for a free electron laser demonstration., Comment: 4 pages, 9 figures

Published

2017

3. Seeded free-electron laser driven by a compact laser plasma accelerator

Author

Labat, M., (0000-0001-9129-4208) Couperus Cabadağ, J. P., (0000-0003-1064-489X) Ghaith, A., (0000-0002-4626-0049) Irman, A., Berlioux, A., Berteaud, P., Blache, F., (0000-0002-1919-8585) Bock, S., Bouvet, F., Briquez, F., (0000-0003-0548-3999) Chang, Y.-Y., Corde, S., (0000-0002-3844-3697) Debus, A., Oliveira, C., Duval, J.-P., Dietrich, Y., El Ajjouri, M., Eisenmann, C., Gautier, J., Gebhardt, R., Grams, S., Helbig, U., Herbeaux, C., Hubert, N., Kitegi, C., Kononenko, O., (0000-0002-8145-5837) Kuntzsch, M., (0000-0003-3089-4087) La Berge, M., Le, S., Leluan, B., Loulergue, A., Malka, V., Marteau, F., Huy N. Guyen, M., Oumbarek-Espinos, D., (0000-0001-7990-9564) Pausch, R., Pereira, D., (0000-0002-4738-6436) Püschel, T., Ricaud, J.-P., Rommeluere, P., Roussel, E., Rousseau, P., (0000-0002-2769-4749) Schöbel, S., Sebdaoui, M., (0000-0001-8965-1149) Steiniger, K., Tavakoli, K., Thaury, C., (0000-0002-6463-5406) Ufer, P., Valleau, M., Vandenberghe, M., Veteran, J., (0000-0003-0390-7671) Schramm, U., Couprie, M.-E., Labat, M., (0000-0001-9129-4208) Couperus Cabadağ, J. P., (0000-0003-1064-489X) Ghaith, A., (0000-0002-4626-0049) Irman, A., Berlioux, A., Berteaud, P., Blache, F., (0000-0002-1919-8585) Bock, S., Bouvet, F., Briquez, F., (0000-0003-0548-3999) Chang, Y.-Y., Corde, S., (0000-0002-3844-3697) Debus, A., Oliveira, C., Duval, J.-P., Dietrich, Y., El Ajjouri, M., Eisenmann, C., Gautier, J., Gebhardt, R., Grams, S., Helbig, U., Herbeaux, C., Hubert, N., Kitegi, C., Kononenko, O., (0000-0002-8145-5837) Kuntzsch, M., (0000-0003-3089-4087) La Berge, M., Le, S., Leluan, B., Loulergue, A., Malka, V., Marteau, F., Huy N. Guyen, M., Oumbarek-Espinos, D., (0000-0001-7990-9564) Pausch, R., Pereira, D., (0000-0002-4738-6436) Püschel, T., Ricaud, J.-P., Rommeluere, P., Roussel, E., Rousseau, P., (0000-0002-2769-4749) Schöbel, S., Sebdaoui, M., (0000-0001-8965-1149) Steiniger, K., Tavakoli, K., Thaury, C., (0000-0002-6463-5406) Ufer, P., Valleau, M., Vandenberghe, M., Veteran, J., (0000-0003-0390-7671) Schramm, U., and Couprie, M.-E.

Abstract

Seeded free-electron laser driven by a compact laser plasma accelerator Free-electron lasers generate high-brilliance coherent radiation at wavelengths spanning from the infrared to the X-ray domains. The recent development of short-wavelength seeded free-electron lasers now allows for unprecedented levels of control on longitudinal coherence, opening new scientific avenues such as ultra-fast dynamics on complex systems and X-ray nonlinear optics. Although those devices rely on state-of-the-art large-scale accelerators, advancements on laser-plasma accelerators, which harness gigavolt-per-centimetre accelerating fields, showcase a promising technology as compact drivers for free-electron lasers. Using such footprint-reduced accelerators, exponential amplification of a shot-noise type of radiation in a self-amplified spontaneous emission configuration was recently achieved. However, employing this compact approach for the delivery of temporally coherent pulses in a controlled manner has remained a major challenge. Here we present the experimental demonstration of a laser-plasma accelerator-driven free-electron laser in a seeded configuration, where control over the radiation wavelength is accomplished. Furthermore, the appearance of interference fringes, resulting from the interaction between the phase-locked emitted radiation and the seed, confirms longitudinal coherence. Building on our scientific achievements, we anticipate a navigable pathway to extreme-ultraviolet wavelengths, paving the way towards smaller-scale free-electron lasers, unique tools for a multitude of applications in industry, laboratories and universities.

Published

2023

4. Tunable High Spatio-Spectral Purity Undulator Radiation from a Transported Laser Plasma Accelerated Electron Beam

Author

Ghaith, A., Oumbarek, D., Roussel, E., Corde, S., Labat, M., André, T., Loulergue, A., Andriyash, I. A., Chubar, O., Kononenko, O., Smartsev, S., Marcouillé, O., Kitégi, C., Marteau, F., Valléau, M., Thaury, C., Gautier, J., Sebban, S., Tafzi, A., Blache, F., Briquez, F., Tavakoli, K., Carcy, A., Bouvet, F., Dietrich, Y., Lambert, G., Hubert, N., El Ajjouri, M., Polack, F., Dennetière, D., Leclercq, N., Rommeluère, P., Duval, J.-P., Sebdaoui, M., Bourgoin, C., Lestrade, A., Benabderrahmane, C., Vétéran, J., Berteaud, P., De Oliveira, C., Goddet, J. P., Herbeaux, C., Szwaj, C., Bielawski, S., Malka, V., and Couprie, M.-E.

Published

2019

5. The ThomX ICS source

Author

Dupraz, K, Alkadi, M, Alves, M, Amoudry, L, Auguste, D, Babigeon, J, Baltazar, M, Benoit, A, Bonis, J, Bonenfant, J, Bruni, C, Cassou, K, Cayla, J, Chabaud, T, Chaikovska, I, Chance, S, Chaumat, V, Chiche, R, Cobessi, A, Cornebise, P, Dalifard, O, Delerue, N, Dorkel, R, Douillet, D, Dugal, J, El Kamchi, N, El Khaldi, M, Ergenlik, E, Favier, P, Fernandez, M, Gamelin, A, Garaut, J, Garolfi, L, Gauron, P, Gauthier, F, Gonnin, A, Grasset, D, Guerard, E, Guler, H, Haissinski, J, Herry, E, Iaquaniello, G, Jacquet, M, Jules, E, Kubytskyi, V, Langlet, M, Le Barillec, T, Ledu, J, Leguidec, D, Leluan, B, Lepercq, P, Letellier-Cohen, F, Marie, R, Marrucho, J, Martens, A, Mageur, C, Mercadier, G, Mercier, B, Mistretta, E, Monard, H, Moutardier, A, Neveu, O, Nutarelli, D, Omeich, M, Peinaud, Y, Petrilli, Y, Pichet, M, Plaige, E, Prevost, C, Rudnicky, P, Soskov, V, Taurigna-Quere, M, Trochet, S, Vallerand, C, Vitez, O, Wicek, F, Wurth, S, Zomer, F, Alexandre, P, Ben El Fekih, R, Berteaud, P, Bouvet, F, Cuoq, R, Diaz, A, Dietrich, Y, Diop, M, Pedeau, D, Dupuy, E, Marteau, F, Helder, D, Hubert, N, Veteran, J, Labat, M, Lestrade, A, Letresor, A, Lopes, R, Loulergue, A, Louvet, M, Marchand, P, El Ajjouri, M, Muller, D, Nadji, A, Nadolski, L, Nagaoka, R, Petit, S, Pollina, J, Ribeiro, F, Ros, M, Salvia, J, Bobault, S, Sebdaoui, M, Sreedharan, R, Bouanai, Y, Hazemann, J, Hodeau, J, Roy, E, Jeantet, P, Lacipiere, J, Robert, P, Horodynski, J, Bzyl, H, Chapelle, C, Biagini, M, Walter, P, Bravin, A, Del Net, W, Lahera, E, Proux, O, Elleaume, H, Cormier, E, Dupraz K., Alkadi M., Alves M., Amoudry L., Auguste D., Babigeon J. -L., Baltazar M., Benoit A., Bonis J., Bonenfant J., Bruni C., Cassou K., Cayla J. -N., Chabaud T., Chaikovska I., Chance S., Chaumat V., Chiche R., Cobessi A., Cornebise P., Dalifard O., Delerue N., Dorkel R., Douillet D., Dugal J. -P., El Kamchi N., El Khaldi M., Ergenlik E., Favier P., Fernandez M., Gamelin A., Garaut J. -F., Garolfi L., Gauron P., Gauthier F., Gonnin A., Grasset D., Guerard E., Guler H., Haissinski J., Herry E., Iaquaniello G., Jacquet M., Jules E., Kubytskyi V., Langlet M., Le Barillec T., Ledu J. -F., Leguidec D., Leluan B., Lepercq P., Letellier-Cohen F., Marie R., Marrucho J. -C., Martens A., Mageur C., Mercadier G., Mercier B., Mistretta E., Monard H., Moutardier A., Neveu O., Nutarelli D., Omeich M., Peinaud Y., Petrilli Y., Pichet M., Plaige E., Prevost C., Rudnicky P., Soskov V., Taurigna-Quere M., Trochet S., Vallerand C., Vitez O., Wicek F., Wurth S., Zomer F., Alexandre P., Ben El Fekih R., Berteaud P., Bouvet F., Cuoq R., Diaz A., Dietrich Y., Diop M., Pedeau D., Dupuy E., Marteau F., Helder D., Hubert N., Veteran J., Labat M., Lestrade A., Letresor A., Lopes R., Loulergue A., Louvet M., Marchand P., El Ajjouri M., Muller D., Nadji A., Nadolski L., Nagaoka R., Petit S., Pollina J. -P., Ribeiro F., Ros M., Salvia J., Bobault S., Sebdaoui M., Sreedharan R., Bouanai Y., Hazemann J. -L., Hodeau J. -L., Roy E., Jeantet P., Lacipiere J., Robert P., Horodynski J. -M., Bzyl H., Chapelle C., Biagini M., Walter P., Bravin A., Del Net W., Lahera E., Proux O., Elleaume H., Cormier E., Dupraz, K, Alkadi, M, Alves, M, Amoudry, L, Auguste, D, Babigeon, J, Baltazar, M, Benoit, A, Bonis, J, Bonenfant, J, Bruni, C, Cassou, K, Cayla, J, Chabaud, T, Chaikovska, I, Chance, S, Chaumat, V, Chiche, R, Cobessi, A, Cornebise, P, Dalifard, O, Delerue, N, Dorkel, R, Douillet, D, Dugal, J, El Kamchi, N, El Khaldi, M, Ergenlik, E, Favier, P, Fernandez, M, Gamelin, A, Garaut, J, Garolfi, L, Gauron, P, Gauthier, F, Gonnin, A, Grasset, D, Guerard, E, Guler, H, Haissinski, J, Herry, E, Iaquaniello, G, Jacquet, M, Jules, E, Kubytskyi, V, Langlet, M, Le Barillec, T, Ledu, J, Leguidec, D, Leluan, B, Lepercq, P, Letellier-Cohen, F, Marie, R, Marrucho, J, Martens, A, Mageur, C, Mercadier, G, Mercier, B, Mistretta, E, Monard, H, Moutardier, A, Neveu, O, Nutarelli, D, Omeich, M, Peinaud, Y, Petrilli, Y, Pichet, M, Plaige, E, Prevost, C, Rudnicky, P, Soskov, V, Taurigna-Quere, M, Trochet, S, Vallerand, C, Vitez, O, Wicek, F, Wurth, S, Zomer, F, Alexandre, P, Ben El Fekih, R, Berteaud, P, Bouvet, F, Cuoq, R, Diaz, A, Dietrich, Y, Diop, M, Pedeau, D, Dupuy, E, Marteau, F, Helder, D, Hubert, N, Veteran, J, Labat, M, Lestrade, A, Letresor, A, Lopes, R, Loulergue, A, Louvet, M, Marchand, P, El Ajjouri, M, Muller, D, Nadji, A, Nadolski, L, Nagaoka, R, Petit, S, Pollina, J, Ribeiro, F, Ros, M, Salvia, J, Bobault, S, Sebdaoui, M, Sreedharan, R, Bouanai, Y, Hazemann, J, Hodeau, J, Roy, E, Jeantet, P, Lacipiere, J, Robert, P, Horodynski, J, Bzyl, H, Chapelle, C, Biagini, M, Walter, P, Bravin, A, Del Net, W, Lahera, E, Proux, O, Elleaume, H, Cormier, E, Dupraz K., Alkadi M., Alves M., Amoudry L., Auguste D., Babigeon J. -L., Baltazar M., Benoit A., Bonis J., Bonenfant J., Bruni C., Cassou K., Cayla J. -N., Chabaud T., Chaikovska I., Chance S., Chaumat V., Chiche R., Cobessi A., Cornebise P., Dalifard O., Delerue N., Dorkel R., Douillet D., Dugal J. -P., El Kamchi N., El Khaldi M., Ergenlik E., Favier P., Fernandez M., Gamelin A., Garaut J. -F., Garolfi L., Gauron P., Gauthier F., Gonnin A., Grasset D., Guerard E., Guler H., Haissinski J., Herry E., Iaquaniello G., Jacquet M., Jules E., Kubytskyi V., Langlet M., Le Barillec T., Ledu J. -F., Leguidec D., Leluan B., Lepercq P., Letellier-Cohen F., Marie R., Marrucho J. -C., Martens A., Mageur C., Mercadier G., Mercier B., Mistretta E., Monard H., Moutardier A., Neveu O., Nutarelli D., Omeich M., Peinaud Y., Petrilli Y., Pichet M., Plaige E., Prevost C., Rudnicky P., Soskov V., Taurigna-Quere M., Trochet S., Vallerand C., Vitez O., Wicek F., Wurth S., Zomer F., Alexandre P., Ben El Fekih R., Berteaud P., Bouvet F., Cuoq R., Diaz A., Dietrich Y., Diop M., Pedeau D., Dupuy E., Marteau F., Helder D., Hubert N., Veteran J., Labat M., Lestrade A., Letresor A., Lopes R., Loulergue A., Louvet M., Marchand P., El Ajjouri M., Muller D., Nadji A., Nadolski L., Nagaoka R., Petit S., Pollina J. -P., Ribeiro F., Ros M., Salvia J., Bobault S., Sebdaoui M., Sreedharan R., Bouanai Y., Hazemann J. -L., Hodeau J. -L., Roy E., Jeantet P., Lacipiere J., Robert P., Horodynski J. -M., Bzyl H., Chapelle C., Biagini M., Walter P., Bravin A., Del Net W., Lahera E., Proux O., Elleaume H., and Cormier E.

Abstract

ThomX is a new generation Compact Compton Source. It is currently commissioned by and at the IJCLab (Laboratoire de physique des 2 infinis - Irène Joliot-Curie (UMR9012)) at Orsay. The first beam is expected at the begining of 2021. The aim of ThomX is to demonstrate the characteristics of an intense and Compact (lab-size) X-ray source based on Compton Scattering. The performances are mostly driven by the laser optical system which is above the state of the art of stored laser power. Proof of principle of various X-ray techniques will be performed thanks to the versatile ThomX beamline. Firstly, this article presents the machine description. Secondly, the issues and limits of the laser system are discussed. Then, the ThomX beamline is described and the machine status conclude the ThomX presentation. Finally, the expected performances for the next years and the possible experiments that can be made with this new machine are detailed.

Published

2020

6. Seeded FEL lasing of the COXINEL beamline driven by the HZDR plasma accelerator

Author

Labat, M., (0000-0001-9129-4208) Couperus Cabadağ, J. P., Ghaith, A., (0000-0002-4626-0049) Irman, A., Berlioux, A., Berteaud, P., Blache, F., (0000-0002-1919-8585) Bock, S., Bouvet, F., Briquez, F., Chang, Y.-Y., Corde, S., (0000-0002-3844-3697) Debus, A., Oliveira, C., Duval, J.-P., Dietrich, Y., El Ajjouri, M., Eisenmann, C., Gautier, J., Gebhardt, R., Grams, S., Helbig, U., Herbeaux, C., Hubert, N., Kitegi, C., Kononenko, O., (0000-0002-8145-5837) Kuntzsch, M., La Berge, M., Le, S., Leluan, B., Loulergue, A., Malka, V., Marteau, F., Huy N. Guyen, M., Oumbarek-Espinos, D., (0000-0001-7990-9564) Pausch, R., Pereira, D., (0000-0002-4738-6436) Püschel, T., Ricaud, J.-P., Rommeluere, P., Roussel, E., Rousseau, P., (0000-0002-2769-4749) Schöbel, S., Sebdaoui, M., (0000-0001-8965-1149) Steiniger, K., Tavakoli, K., Thaury, C., (0000-0002-6463-5406) Ufer, P., Valleau, M., Vandenberghe, M., Veteran, J., (0000-0003-0390-7671) Schramm, U., Couprie, M.-E., Labat, M., (0000-0001-9129-4208) Couperus Cabadağ, J. P., Ghaith, A., (0000-0002-4626-0049) Irman, A., Berlioux, A., Berteaud, P., Blache, F., (0000-0002-1919-8585) Bock, S., Bouvet, F., Briquez, F., Chang, Y.-Y., Corde, S., (0000-0002-3844-3697) Debus, A., Oliveira, C., Duval, J.-P., Dietrich, Y., El Ajjouri, M., Eisenmann, C., Gautier, J., Gebhardt, R., Grams, S., Helbig, U., Herbeaux, C., Hubert, N., Kitegi, C., Kononenko, O., (0000-0002-8145-5837) Kuntzsch, M., La Berge, M., Le, S., Leluan, B., Loulergue, A., Malka, V., Marteau, F., Huy N. Guyen, M., Oumbarek-Espinos, D., (0000-0001-7990-9564) Pausch, R., Pereira, D., (0000-0002-4738-6436) Püschel, T., Ricaud, J.-P., Rommeluere, P., Roussel, E., Rousseau, P., (0000-0002-2769-4749) Schöbel, S., Sebdaoui, M., (0000-0001-8965-1149) Steiniger, K., Tavakoli, K., Thaury, C., (0000-0002-6463-5406) Ufer, P., Valleau, M., Vandenberghe, M., Veteran, J., (0000-0003-0390-7671) Schramm, U., and Couprie, M.-E.

Abstract

Laser Plasma Accelerators (LPAs), harnessing gigavolt-per-centimeter accelerating fields, can generate high peak current, low emittance and GeV class electron beams paving the way for the realization of future compact free-electron lasers (FELs). Here, we report on the commissioning of the COXINEL beamline driven by the HZDR plasma accelerator and experimental demonstration of FEL lasing at 270 nm in a seeded configuration. Control over the radiation wavelength is achieved with an improved bandwidth stability. Furthermore, the appearance of interference fringes, resulting from the interaction between the phase-locked emitted radiation and the seed, confirms longitudinal coherence, representing a key feature of such a seeded FEL. These results are cross-checked with simulations, ELEGANT for beam optics and GENESIS for FEL radiation. We anticipate a navigable pathway toward smaller-scale free-electron lasers at extreme ultra-violet wavelengths.

Published

2022

7. Towards a free electron laser using laser plasma acceleration on COXINEL

Author

Couprie, M. E., primary, André, T., additional, Blache, F., additional, Bouvet, F., additional, Briquez, F., additional, Dennetière, D., additional, Dietrich, Y., additional, de Oliviera, C., additional, Duval, J. P., additional, Ajjouri, M. El, additional, Ghaith, A., additional, Herbeaux, C., additional, Hubert, N., additional, Khojoyan, M., additional, Kitégi, C., additional, Labat, M., additional, Leclercq, N., additional, Lestrade, A., additional, Loulergue, A., additional, Marcouillé, O., additional, Marteau, F., additional, Oumbarek, D., additional, Polack, F., additional, Rommeluère, P., additional, Sebdaoui, M., additional, Tavakoli, K., additional, Valléau, M., additional, Andriyash, I. A., additional, Benabderrahmane, C., additional, Corde, S., additional, Gautier, J., additional, Goddet, J. P., additional, Lambert, G., additional, Mahieu, B., additional, Phuoc, K. Ta, additional, Tafzi, A., additional, Thaury, C., additional, Smartsev, S., additional, Malka, V., additional, Roussel, E., additional, Evain, C., additional, Szwaj, C., additional, and Bielawski, S., additional

Published

2019

8. Energy spread tuning of a laser-plasma accelerated electron beam in a magnetic chicane.

Author

Roussel, E, André, T, Andriyash, I, Blache, F, Bouvet, F, Corde, S, Espinos, D Oumbarek, Ghaith, A, Goddet, J-P, Kitegi, C, Kononenko, O, Labat, M, Lambert, G, Lestrade, A, Loulergue, A, Marteau, F, Marcouillé, O, Sebdaoui, M, Tafzi, A, and Tavakoli, K

Subjects

FREE electron lasers, RELATIVISTIC electron beams, ELECTRON beams, UNDULATOR radiation, RADIATION trapping, FOCUS (Optics), LIGHT sources

Abstract

Laser-plasma accelerators (LPA) deliver relativistic electron beams with high peak current and low emittance, with energies up to the GeV-level in only few centimetres. However, the divergence and the energy spread of these beams remain too large for potential light source applications. A magnetic transfer line can be used to manipulate the electron beam phase-space and select the transmitted energies with a slit located at its center. We will show that with a proper focusing optics along the line, one can tune the energy spread of the beam at a given energy without loss and produce undulator radiation with controlled bandwidth. We present analytic studies, numerical simulations and experimental results on the controled electron beam transport and application to undulator radiation with a control of the bandwidth. [ABSTRACT FROM AUTHOR]

Published

2020

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

Author

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

Published

2018

10. Control of laser plasma accelerated electrons for light sources

Author

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

Published

2018

11. Variable high gradient permanent magnet quadrupole (QUAPEVA)

Author

Marteau, F., primary, Ghaith, A., additional, N'Gotta, P., additional, Benabderrahmane, C., additional, Valléau, M., additional, Kitegi, C., additional, Loulergue, A., additional, Vétéran, J., additional, Sebdaoui, M., additional, André, T., additional, Le Bec, G., additional, Chavanne, J., additional, Vallerand, C., additional, Oumbarek, D., additional, Cosson, O., additional, Forest, F., additional, Jivkov, P., additional, Lancelot, J. L., additional, and Couprie, M. E., additional

Published

2017

12. First electron beam measurements on COXINEL

Author

André, T., Andriyash, I., Basset, C., Benabderrahmane, C., Berteaud, P., Bonnin, S., Bouvet, F., Briquez, F., Cassinari, L., Chapuis, L., Couprie, M. E., Deitriech, Y., Dennetière, D., Oliviera, C., Duval, J. P., El Ajjouri, M., El Ajjouri, T., Gattoni, P., Herbeaux, C., Hubert, N., Khojoyan, M., Labat, M., Leclercq, N., Lestrade, A., Loulergue, A., Marcouillé, O., Marteau, F., Pierrot, P., Polack, F., Ribeiro, F., Ricaud, J. P., Rommmeluère, P., Sebdaoui, M., Tavakoli, K., Tordeux, M. A., Valléau, M., Vétéran, J., Zerbib, D., Bielawski, S., Evain, C., Christophe Szwaj, Roussel, E., Gautier, J., Guillaume, E., Ta Phuoc, K., Lambert, G., Mahieu, B., Malka, V., Rousse, A., and Thaury, C.

13. Seeded free-electron laser driven by a compact laser plasma accelerator

Author

Labat, M. (Marie), Cadabag, J.C. (Jurjen Couperus), Ghaith, A. (Amin), Irman, A. (Arie), Berlioux, A. (Anthony), Berteaud, P. (Philippe), Blache, F. (Frédéric), Bock, S. (Stefan), Bouvet, F. (François), Briquez, F. (Fabien), Chang, Y-Y. (Yen-Yu), Corde, S. (Sébastien), Debus, A. (Alexander), de Oliveira, C. (Carlos), Duval, J-P. (Jean-Pierre), Dietrich, Y. (Yannick), Ajjouri, M.E. (Moussa El), Eisenmann, C. (Christoph), Gautier, J. (Julien), Gebhardt, R. (René), Grams, S. (Simon), Helbig, U. (Uwe), Herbeaux, C. (Christian), Hubert, N. (Nicolas), Kitegi, C. (Charles), Kononenko, O. (Olena), Kuntzsch, M. (Michael), Laberge, M. (Maxwell), Lé, S. (Stéphane), Leluan, B. (Bruno), Loulergue, A. (Alexandre), Malka, V. (Victor), Marteau, F. (Fabrice), Guyen, M.H.N. (Manh Huy N), Oumbarek-Espinos, D. (Driss), Pausch, R. (Richard), Pereira, D. (Damien), Püschel, T. (Thomas), Ricaud, J-P. (Jean-Paul), Rommeluere, P. (Patrick), Roussel, E. (Eléonore), Rousseau, P. (Pascal), Schöbel, S. (Susanne), Sebdaoui, M. (Mourad), Steiniger, K. (Klaus), Tavakoli, K. (Keihan), Thaury, C. (Cedric), Ufer, P. (Patrick), Valléau, M. (Mathieu), Vandenberghe, M. (Marc), Vétéran, J. (José), Schramm, U. (Ulrich), Couprie, M. (Marie), Synchrotron SOLEIL [SSOLEIL], Helmholtz-Zentrum Dresden-Rossendorf [HZDR], Institute of Radiation Physics [Dresden], Weizmann Institute of Science [Rehovot, Israël], DYnamique des Systèmes COmplexes [DYSCO], and Laboratoire de Physique des Lasers, Atomes et Molécules - UMR 8523 [PhLAM]

Abstract

Free-electron lasers generate high-brilliance coherent radiation at wavelengths spanning from the infrared to the X-ray domains. The recent development of short-wavelength seeded free-electron lasers now allows for unprecedented levels of control on longitudinal coherence[1], opening new scientific avenues as ultra-fast dynamics on complex systems and X-ray nonlinear optics. While those devices rely on state-of-the-art large-scale accelerators, advancements on laser-plasma accelerators, which harness giga-volt-per-centimeter accelerating fields, showcase a promising technology as compact drivers for free-electron lasers. Using such miniaturized accelerators, exponential amplification of a shot-noise type of radiation in a self-amplified spontaneous emission configuration was recently achieved [2]. However, employing this compact approach for the delivery of temporally coherent pulses in a controlled manner remained a major challenge. Here, we present the experimental demonstration of a laser-plasma accelerator driven free-electron laser in a seeded configuration, where control over the radiation wavelength is accomplished. Furthermore, the appearance of interference fringes, resulting from the interaction between the phase-locked emitted radiation and the seed, confirms longitudinal coherence. Building on our scientific achievements, we anticipate a straightforward scaling to extreme-ultraviolet wavelengths, paving the way towards university-scale free-electron lasers, unique tools for a multitude of applications. [1] Meyer, M. FELs of europe: Whitebook on science with free electron lasers 8–19 (2016). [2] Wang, W. et al. Free-electron lasing at 27 nanometres based on a laser wakefield accelerator.

14. The ThomX ICS source

Author

Kevin Dupraz, Muath Alkadi, Manuel Alves, Loic Amoudry, Didier Auguste, Jean-Luc Babigeon, Michel Baltazar, Alain Benoit, Julien Bonis, Jean Bonenfant, Christelle Bruni, Kevin Cassou, Jean-Noël Cayla, Thomas Chabaud, Iryna Chaikovska, Sophie Chance, Vincent Chaumat, Ronic Chiche, Alain Cobessi, Patrick Cornebise, Olivier Dalifard, Nicolas Delerue, Remy Dorkel, Denis Douillet, Jean-Phillipe Dugal, Noureddine El Kamchi, Mohamed El Khaldi, Ezgi Ergenlik, Pierre Favier, Marco Fernandez, Alexis Gamelin, Jean-Francois Garaut, Luca Garolfi, Philippe Gauron, Frédéric Gauthier, Alexandre Gonnin, Denis Grasset, Eric Guerard, Hayg Guler, Jacques Haissinski, Emmanuel Herry, Gregory Iaquaniello, Marie Jacquet, Eric Jules, Vlacheslav Kubytskyi, Marc Langlet, Titouan Le Barillec, Jean-François Ledu, Damien Leguidec, Bruno Leluan, Pierre Lepercq, Frédéric Letellier-Cohen, Rodolphe Marie, Jean-Claude Marrucho, Aurélien Martens, Christophe Mageur, Gabriel Mercadier, Bruno Mercier, Eric Mistretta, Hugues Monard, Alexandre Moutardier, Olivier Neveu, Daniele Nutarelli, Maher Omeich, Yann Peinaud, Yann Petrilli, Marc Pichet, Eric Plaige, Christophe Prévost, Philippe Rudnicky, Viktor Soskov, Monique Taurigna-Quéré, Stéphane Trochet, Cynthia Vallerand, Olivier Vitez, François Wicek, Sébastien Wurth, Fabian Zomer, Patrick Alexandre, Rachid Ben El Fekih, Philippe Berteaud, François Bouvet, Renaud Cuoq, Antonio Diaz, Yannick Dietrich, Massamba Diop, Dominique Pedeau, Eric Dupuy, Fabrice Marteau, Dias Helder, Nicolas Hubert, José Veteran, Marie Labat, Alain Lestrade, Antoine Letrésor, Robert Lopes, Alexandre Loulergue, Marc Louvet, Patrick Marchand, Moussa El Ajjouri, Didier Muller, Amor Nadji, Laurent Nadolski, Ryutaro Nagaoka, Sylvain Petit, Jean-Pierre Pollina, Fernand Ribeiro, Manuel Ros, Julien Salvia, Sébastien Bobault, Mourad Sebdaoui, Rajesh Sreedharan, Yazid Bouanai, Jean-Louis Hazemann, Jean-Louis Hodeau, Emmanuel Roy, Philippe Jeantet, Jérôme Lacipière, Pierre Robert, Jean-Michel Horodynski, Harold Bzyl, Christophe Chapelle, Marica Biagini, Philippe Walter, Alberto Bravin, William Del Net, Eric Lahéra, Olivier Proux, Hélène Elleaume, Eric Cormier, Laboratoire de Physique des 2 Infinis Irène Joliot-Curie (IJCLab), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Synchrotron SOLEIL (SSOLEIL), Centre National de la Recherche Scientifique (CNRS), Laboratoire de l'Accélérateur Linéaire (LAL), Centre National de la Recherche Scientifique (CNRS)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Sud - Paris 11 (UP11), Matériaux, Rayonnements, Structure (MRS), Institut Néel (NEEL), Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA), SERAS (SERAS), Ingénierie Radioprotection Sûreté Démantèlement (IRSD), Laboratori Nazionali di Frascati (LNF), Istituto Nazionale di Fisica Nucleare (INFN), Laboratoire d'Archéologie Moléculaire et Structurale (LAMS), Institut de Chimie du CNRS (INC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), European Synchrotron Radiation Facility (ESRF), Observatoire des Sciences de l'Univers de Grenoble (OSUG ), Institut national des sciences de l'Univers (INSU - CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Grenoble Alpes (UGA), Rayonnement Synchrotron et Recherche Medicale (RSRM), European Synchrotron Radiation Facility (ESRF)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut National de la Santé et de la Recherche Médicale (INSERM), Institut Universitaire de France (IUF), Ministère de l'Education nationale, de l’Enseignement supérieur et de la Recherche (M.E.N.E.S.R.), LETELLIER, Frédéric, Université Paris-Sud - Paris 11 (UP11)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS), Matériaux, Rayonnements, Structure (NEEL - MRS), Service Etudes et Réalisation d'Appareillages Scientifiques (NEEL - SERAS), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut de Chimie du CNRS (INC)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Institut national des sciences de l'Univers (INSU - CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)-Université Grenoble Alpes (UGA)-Météo-France, Dupraz, K, Alkadi, M, Alves, M, Amoudry, L, Auguste, D, Babigeon, J, Baltazar, M, Benoit, A, Bonis, J, Bonenfant, J, Bruni, C, Cassou, K, Cayla, J, Chabaud, T, Chaikovska, I, Chance, S, Chaumat, V, Chiche, R, Cobessi, A, Cornebise, P, Dalifard, O, Delerue, N, Dorkel, R, Douillet, D, Dugal, J, El Kamchi, N, El Khaldi, M, Ergenlik, E, Favier, P, Fernandez, M, Gamelin, A, Garaut, J, Garolfi, L, Gauron, P, Gauthier, F, Gonnin, A, Grasset, D, Guerard, E, Guler, H, Haissinski, J, Herry, E, Iaquaniello, G, Jacquet, M, Jules, E, Kubytskyi, V, Langlet, M, Le Barillec, T, Ledu, J, Leguidec, D, Leluan, B, Lepercq, P, Letellier-Cohen, F, Marie, R, Marrucho, J, Martens, A, Mageur, C, Mercadier, G, Mercier, B, Mistretta, E, Monard, H, Moutardier, A, Neveu, O, Nutarelli, D, Omeich, M, Peinaud, Y, Petrilli, Y, Pichet, M, Plaige, E, Prevost, C, Rudnicky, P, Soskov, V, Taurigna-Quere, M, Trochet, S, Vallerand, C, Vitez, O, Wicek, F, Wurth, S, Zomer, F, Alexandre, P, Ben El Fekih, R, Berteaud, P, Bouvet, F, Cuoq, R, Diaz, A, Dietrich, Y, Diop, M, Pedeau, D, Dupuy, E, Marteau, F, Helder, D, Hubert, N, Veteran, J, Labat, M, Lestrade, A, Letresor, A, Lopes, R, Loulergue, A, Louvet, M, Marchand, P, El Ajjouri, M, Muller, D, Nadji, A, Nadolski, L, Nagaoka, R, Petit, S, Pollina, J, Ribeiro, F, Ros, M, Salvia, J, Bobault, S, Sebdaoui, M, Sreedharan, R, Bouanai, Y, Hazemann, J, Hodeau, J, Roy, E, Jeantet, P, Lacipiere, J, Robert, P, Horodynski, J, Bzyl, H, Chapelle, C, Biagini, M, Walter, P, Bravin, A, Del Net, W, Lahera, E, Proux, O, Elleaume, H, and Cormier, E

Subjects

Beamline, ThomX, [PHYS.PHYS.PHYS-ACC-PH]Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph], General Physics and Astronomy, 01 natural sciences, law.invention, 010309 optics, X-ray, Optics, law, 0103 physical sciences, Laser power scaling, Physics, Machine description, 010308 nuclear & particles physics, business.industry, Compton scattering, [PHYS.PHYS.PHYS-ACC-PH] Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph], Laser, High power Fabry-Perot cavity, lcsh:QC1-999, Proof of concept, Compact compton source, business, Beam (structure), lcsh:Physics

Abstract

International audience; ThomX is a new generation Compact Compton Source. It is currently commissioned by and at the IJCLab (Laboratoire de physique des 2 infinis - Irène Joliot-Curie (UMR9012)) at Orsay. The first beam is expected at the begining of 2021. The aim of ThomX is to demonstrate the characteristics of an intense and Compact (lab-size) X-ray source based on Compton Scattering. The performances are mostly driven by the laser optical system which is above the state of the art of stored laser power. Proof of principle of various X-ray techniques will be performed thanks to the versatile ThomX beamline. Firstly, this article presents the machine description. Secondly, the issues and limits of the laser system are discussed. Then, the ThomX beamline is described and the machine status conclude the ThomX presentation. Finally, the expected performances for the next years and the possible experiments that can be made with this new machine are detailed.

Published

2020