Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 1 Office of Science Strong Field Electrodynamics of Thin Foils S. S. Bulanov Lawrence Berkeley National Laboratory, Berkeley, CA We acknowledge support.

Published byBertina Peters Modified over 7 years ago

Similar presentations

Presentation on theme: "1 1 Office of Science Strong Field Electrodynamics of Thin Foils S. S. Bulanov Lawrence Berkeley National Laboratory, Berkeley, CA We acknowledge support."— Presentation transcript:

1 1 1 Office of Science Strong Field Electrodynamics of Thin Foils S. S. Bulanov Lawrence Berkeley National Laboratory, Berkeley, CA We acknowledge support from the Office of Science of the US DOE under Contract No. DE-AC02- 05CH11231. Advanced Accelerator Concepts Workshop (AAC 2016), July 31 – August 5, National Harbor, MD

2 2 2 Office of Science In Collaboration with 2 ATAP Division, LBNL E. Esarey C. B. Schroeder W. P. Leemans Pisa University F. Pegoraro Kansai Photon Science Institute, JAEA T. Zh. Esirkepov M. Kando S. V. Bulanov S. Rykovanov

3 3 3 Office of Science The Ion Acceleration Mechanism is Determined by Laser Intensity and Target Surface Density Applications: Radiography, Deflectometry, Cancer Therapy, Injection into conventional accelerators, Fast Ignition, Isochoric heating of matter, Positron Emission Tomography, Nuclear Physics… TNSA Laser: Low Intensity Target: Thick solid density foils Ion Energy: ~100 MeV RPA & CE Laser: High Intensity Target: Thin solid density foils Ion Energy: hundreds of MeV MVA Laser: High Intensity Target: Near Critical Density slab Ion Energy: hundreds of MeV to GeV S. S. Bulanov, et al., Physics of Plasmas 23, 056703 (2016); Ion Energy ~ Laser Power 2/3 Ion Energy ~ Laser Power Ion Energy ~ Laser Power 1/2

4 4 4 Office of Science Advanced Acceleration Mechanisms are needed to generate ion beams with energies needed for applications TNSA Laser: Low Intensity Target: Thick solid density foils Ion Energy: ~100 MeV RPA & CE Laser: High Intensity Target: Thin solid density foils Ion Energy: hundreds of MeV MVA Laser: High Intensity Target: Near Critical Density slab Ion Energy: hundreds of MeV to GeV S. S. Bulanov, et al., Physics of Plasmas 23, 056703 (2016);

5 5 5 Office of Science Radiation Pressure Acceleration (receding relativistic mirror) -Co-propagation configuration -EM wave “pushes” relativistic mirror -“Receding mirror”: ions are accelerated by radiation pressure T. Esirkepov, et al., Phys. Rev. Lett. 92, 175003 (2004)

6 6 6 Office of Science Strong Field Electrodynamics of a thin foil: Equations in 1D Electron layer Ion layer Normalized area charge density S. Bulanov et al., PoP (2013)

7 7 7 Office of Science The Electric and Magnetic Field Expressions Describe the EM Wave Emitted by the Thin Layer (1D Electric Charge) S. Bulanov et al., PoP (2013)

8 8 8 Office of Science The EM Fields at the Layer and Acting on the Layer S. Bulanov et al., PoP (2013)

9 9 9 Office of Science The Rate of Radiative Energy Loss Depends Only on the Momentum Component Along the Layer S. Bulanov et al., PoP (2013)

10 10 Office of Science The Radiation Losses Lead to a Finite Acceleration of the Layer 4532145321 S. Bulanov et al., PoP (2013)

11 11 Office of Science The 1D Electrodynamics of Thin Foils Can be Used to Study Different Phenomena in Laser-Thin Foil Interactions -Relativistic Oscillating Mirrors -Flying Relativistic Mirrors -Ion Acceleration in the RPA regime

12 12 Office of Science Relativistic Oscillating Mirror and Relativistic Flying Mirror in 1D Electrodynamics Momentum and coordinate Reflected pulses S. Bulanov et al., PoP (2013)

13 13 Office of Science Ion Acceleration in Radiation Pressure Acceleration Regime Reveals Complex Dynamics of electrons and ions

14 14 Office of Science 1D Electrodynamics for Chirped Standing Wave Acceleration of Ions F. Mackenroth, A. Gonoskov, and M. Marklund, PRL 2016 chirped not chirped

15 15 Office of Science Conclusions -The theory of the interaction of relativistically strong EM fields with foil targets is formulated, based on the thin layer model of the one-dimensional electrodynamics of charged particles. -Within this framework, the generation of high order harmonics in the relativistic regime occurs through the electromagnetic wave reflection, or collective backward scattering. - The theory can be used for the characterization of laser driven ion acceleration of thin foils in different regimes

16 16 Office of Science Thank you!

Download ppt "1 1 Office of Science Strong Field Electrodynamics of Thin Foils S. S. Bulanov Lawrence Berkeley National Laboratory, Berkeley, CA We acknowledge support."

Similar presentations

Rutherford Appleton Laboratory Three mechanisms interact to cause ion acceleration in PW laser interactions Relativistic electrons expelled by the ponderomotive.

Rutherford Appleton Laboratory Three mechanisms interact to cause ion acceleration in PW laser interactions Relativistic electrons expelled by the ponderomotive.
The photon, the quantum of light

The photon, the quantum of light
Particle acceleration in plasma By Prof. C. S. Liu Department of Physics, University of Maryland in collaboration with V. K. Tripathi, S. H. Chen, Y. Kuramitsu,

Particle acceleration in plasma By Prof. C. S. Liu Department of Physics, University of Maryland in collaboration with V. K. Tripathi, S. H. Chen, Y. Kuramitsu,
High Intensity Laser Electron Scattering David D. Meyerhofer IEEE Journal of Quantum Electronics, Vol. 33, No. 11, November 1997.

High Intensity Laser Electron Scattering David D. Meyerhofer IEEE Journal of Quantum Electronics, Vol. 33, No. 11, November 1997.
0 Relativistic induced transparency and laser propagation in an overdense plasma Su-Ming Weng Theoretical Quantum Electronics (TQE), Technische Universität.

0 Relativistic induced transparency and laser propagation in an overdense plasma Su-Ming Weng Theoretical Quantum Electronics (TQE), Technische Universität.
Contour plots of electron density 2D PIC in units of  [n |e|] cr wake wave breaking accelerating field laser pulse Blue:electron density green: laser.

Contour plots of electron density 2D PIC in units of  [n |e|] cr wake wave breaking accelerating field laser pulse Blue:electron density green: laser.
Charged-particle acceleration in PW laser-plasma interaction X. T. He Institute of Applied Physics and Computational Mathematics, Beijing 100088 Present.

Charged-particle acceleration in PW laser-plasma interaction X. T. He Institute of Applied Physics and Computational Mathematics, Beijing Present.
西湖国际聚变理论与模拟研讨会 西湖国际聚变理论与模拟研讨会 M. Y. Yu 郁明阳 Institute for Fusion Theory and Simulation Zhejiang University Hangzhou 2008.12.26.

西湖国际聚变理论与模拟研讨会 西湖国际聚变理论与模拟研讨会 M. Y. Yu 郁明阳 Institute for Fusion Theory and Simulation Zhejiang University Hangzhou
Charged-particle acceleration in PW laser-plasma interaction

Charged-particle acceleration in PW laser-plasma interaction
1 Introduction to Plasma Immersion Ion Implantation Technologies Emmanuel Wirth.

1 Introduction to Plasma Immersion Ion Implantation Technologies Emmanuel Wirth.
SCT-2012, Novosibirsk, June 8, 2012 SHOCK WAVE PARTICLE ACCELERATION in LASER- PLASMA INTERACTION G.I.Dudnikova, T.V.Leseykina ICT SBRAS.

SCT-2012, Novosibirsk, June 8, 2012 SHOCK WAVE PARTICLE ACCELERATION in LASER- PLASMA INTERACTION G.I.Dudnikova, T.V.Leseykina ICT SBRAS.
Structure of Atoms Rutherford's model of the atom was a great advance, however, it does not give an satisfactory treatment of the electrons. To improve.

Structure of Atoms Rutherford's model of the atom was a great advance, however, it does not give an satisfactory treatment of the electrons. To improve.
Sub-THz Component of Large Solar Flares Emily Ulanski December 9, 2008 Plasma Physics and Magnetohydrodynamics.

Sub-THz Component of Large Solar Flares Emily Ulanski December 9, 2008 Plasma Physics and Magnetohydrodynamics.
High-Mach Number Relativistic Ion Acoustic Shocks J. Fahlen and W.B. Mori University of California, Los Angeles.

High-Mach Number Relativistic Ion Acoustic Shocks J. Fahlen and W.B. Mori University of California, Los Angeles.
CHEM 515 Spectroscopy Lecture # 1.

CHEM 515 Spectroscopy Lecture # 1.
Acceleration of a mass limited target by ultra-high intensity laser pulse A.A.Andreev 1, J.Limpouch 2, K.Yu.Platonov 1 J.Psikal 2, Yu.Stolyarov 1 1. ILPh.

Acceleration of a mass limited target by ultra-high intensity laser pulse A.A.Andreev 1, J.Limpouch 2, K.Yu.Platonov 1 J.Psikal 2, Yu.Stolyarov 1 1. ILPh.
Chapter 2: Particle Properties of Waves

Chapter 2: Particle Properties of Waves
Laser acceleration of electrons and ions: principles, issues, and applications Alexander Lobko Institute for Nuclear Problems, BSU Minsk Belarus.

Laser acceleration of electrons and ions: principles, issues, and applications Alexander Lobko Institute for Nuclear Problems, BSU Minsk Belarus.
Welcome to Physics--Jump in!. What is If it living it is biology. If it is chemicals it is chemistry If it is rocks it is geology Physics is everything.

Welcome to Physics--Jump in!. What is If it living it is biology. If it is chemicals it is chemistry If it is rocks it is geology Physics is everything.
Radiation therapy is based on the exposure of malign tumor cells to significant but well localized doses of radiation to destroy the tumor cells. The.

Radiation therapy is based on the exposure of malign tumor cells to significant but well localized doses of radiation to destroy the tumor cells. The.

Similar presentations

Ads by Google