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Present to International Conference on Frontier of Science Charged-particle acceleration in PW laser-plasma interaction X. T. He Institute of Applied Physics and Computational Mathematics, Beijing 100088 Outline 1. Introduction 2. Electron acceleration by PW laser 3. Proton acceleration by normal and oblique incident PW lasers 4. Plasma density effect on ion beam acceleration 5. Heavy ion acceleration and quark-gluon plasma research 6. Conclusions and discussions 1.Introduction With development of CPA technology, short-pulse and high-intense laser (PW-1015w) system can provide intensities 1018-21w/cm2 for each beam. Interaction of the petawatt (PW) laser with matter may accelerate charged particles (electrons, protons and heavy ions) to kinetic energy over GeV. Could PW laser beam accelerating particles serve for high energy physics instead of (or parallel to) accelerators RHIC and LHC in future? So far only the PW lasers of x100J/0.5ps are used for experiments. New PW lasers are being constructed : 10kJ/4 beams/1-10ps in Japan, 2x2.6kJ/2 beams/1-10ps and NIF in US, 1.5kJ/1 beam/1-5ps (and future SG-IV) in China will be operating in 2-3 years. In this presentation, charged particle acceleration mechanisms and application to QGP research are presented and discussed 2. Electron acceleration by PW laserdriven wake field Wake-field: Electrons are accelerated, like surf in laser-driven plasma wave Laser intensity 3x1020w/cm2,electron energy >300MeV is observed (Mangles et al., PRL94(05) Some electrons are trapped and accelerated in the bubble as shown in the bubble black rod. 2. Electron resonance acceleration in PW laser-plasma interaction vz 1 Resonant acceleration : ~ 1 g (r )(1 ) vg Where vz axial velocity for electron, v g group velocity for laser. 200 400 20 2 mc (MeV) 2 L (z-z )/ L a0=16 (IL=3.16x10 W/cm ) v =0.99 (n =0.08n ) g 0 cr B0=24 MG B0Z=5 MG 100 0 00 200 55 10 15 20 0 25 time (ps) Maximal kinetic energy ~180MeV Maximal kinetic energy ~170MeV for for Gaussian CP laser planar laser (Liu and He, PRE2004) 3. Proton acceleration by PW laser incident on normal direction Electrons driven out of the target front side by PW laser ponderomotive force set up electrostatic fields that accelerate protons backward against the PW laser direction. On the other hand, the electrons in the target front side can also be accelerated by ponderomotive force, a thin Debye sheath at the garget rear side is generated when electrons penetrate through the target. 3. Proton acceleration by PW laser incident on normal direction When PW laser beam propagates along the target normal direction or a small angle, the proton emission cone is also aligned at same as direction or cone. Furthermore, the electron sheath has a Gaussian profile, and the central region as well as the edge of the sheath will expel proton normal to the surface. The Bragg peak proton energy is at the center the resulting Gaussian proton beam (Zhang and He, IAEA06). Electric field E=30GV/cm, laser intensity 1020w/cm2 Energetic proton in the rear CH target 3. Proton acceleration by PW laser incident on normal direction Protons by PW laser acceleration was verified by experiments and simulations, see review papers: Plasma phys. Controlled Fusion 47, B841(05) by M. Roth et al and Fusion Science and Tech. 49, 412 (06) by M. Borghesi. Experimental results are shown in the following plot. Laser intensities of up to 1020 w/cm2, But the pulse duration is < 100fs. 3. Proton acceleration by PW laser incident on normal direction Protons by PW laser acceleration was verified by experiments and simulations, see review papers: Plasma phys. Controlled Fusion 47, B841(05) by M. Roth et al and Fusion Science and Tech. 49, 412 (06) by M. Borghesi. Experimental results are shown in the following plot. Laser intensities of up to 1020 w/cm2, But the pulse duration is < 100fs. 3. Larger oblique angle of PW laser effect on proton acceleration Numerical simulation conditions (APL,90, 031503(07) by Zhou and He): (a) Laser intensity I0=3x1020 w/cm2. PF-PIC. (b) C+ H2+ foil (5eV), thickness: 19< z / micron <26; density: in the propagating direction, there is a linear rise to n0 within 1.0 micron on both sides, n0/100 at z=19. (c) (d) 0 ,60 =0.2, 1, 3 g/cm3 3. Larger oblique angle of PW laser effect on proton acceleration Protons and carbon ions accelerated from the front and rear surfaces of CH target deviate from the normal direction (I=3x1020 w/cm2) due to non-Gaussian asymmetric sheath field at the target surfaces. 3. Larger oblique angle of PW laser effect on proton acceleration 3. Larger oblique angle of PW laser effect on proton acceleration 0 , fast electrons are of x-like angle distribution, p / p// 1 ; 60 , fast electrons along the target surface generated by surface quasi-static EM fields. Proton density distribution is no longer of a symmetrical Gaussian-like structure. In particular, two-Bragg energy peaks are observed in the backward-accelerated proton beam. It confirms that the front-surface electrons confined by the EM fields can seriously influence on the emission of the backward-accelerated protons. The conversion efficiencies of laser energy into electron energy: 35% (0。) and 18% ( 60。) for >1 MeV. Electronproton efficiencies : 14% (0。) and 25% (60。) for >2MeV. 4. Plasma density effect on Ion beam acceleration Relativistic electrons move across the foil, JAP (07) by Zhou, Yu and He 4. Plasma density effect on Ion beam acceleration 4. Plasma density effect on Ion beam acceleration I. Lower density II. Density 1g/cm3 III. Better collimation, Lower energy 4. Plasma density effect on Ion beam acceleration 5. Heavy ion acceleration and quark-gluon plasma (1). Finding quark and gluon and understanding QGP in laboratory are an essential mission in high energy physics and high energy astrophysics (2). Heavy ion beam colliding in the frame of center of mass has achieved QGP information. In the past 2-3 years, gold nuclei are accelerated by RHIC and collide in the frame of center of mass and the QGP like ideal fluid state was observed. The QGP state rapidly reaches thermo-equilibrium like equilibrium plasma and can be explained by the fluid equations. 5. Heavy ion acceleration and quark-gluon plasma T μν Motion equation for QGP: 0 μ x ε (ε P) 0 Equation for energy density : τ τ For ideal massless QG gas, ε π2 4 T Pressure: P g t ot 3 90 g tot [ g g 7 g q g q ], g g 8 2, gtot 37 8 The Solution: ε(τ) ε(τ) τ 0 ε(τ0 ) ε 0 τ T ( ) 0 T ( 0 ) 4/ 3 1/ 3 5. Heavy ion acceleration and quark-gluon plasma . Heavy ion beam (high-Z charged particles) could also be accelerated to 100 GeV/ nucleon by PW laser with intensity over 1024 w/cm2 that could be reached by multi-PW beam irradiation. . PW laser can be used to explore QGP instead of the traditional accelerators, such as RHIC and other new one. Relativistic momentum equation or relativistic Vlasov equation can be used to investigate such heavy ion beam 5. Heavy ion acceleration and quark-gluon plasma Numerical simulation shows that when laser (intensity I≥1023W/cm2 ) interacts with CH target foil (thickness l~λ), kinetic energy of protons can reach over 4GeV . The laser piston model shows that protons undergo two stages: longitudinal field E / / 2πenel acceleration, which is generated by charge separation; laser light reflection to transfer laser energy to target with reflectivity κ (1 1 ) . 4γ 2 5. Heavy ion acceleration and quark-gluon plasma T. Esirkepov et al. PRL 92, 175003 (2004). 5. Heavy ion acceleration and quark-gluon plasma From numerical simulation and analytical estimation, as t , ion kinetic energy asymptotically ik mi c 2 (3It / nelmi c)1/ 3 where I is laser intensity, l is foil thickness 2 L L L ~ max ( ik) 2 2 L N i mi c N i Ni For L 10kJ ( / 1m), ne 5.5 1022 cm 3 , l 1m 2 The acceleration time tac ( L / N i mc 2 ) 2 t L 16 ps 3 and acceleration length Xac=ctac=4.8mm ik 30GeV 5. Heavy ion acceleration and quark-gluon plasma We may estimate kinetic energy of heavy ions from relativistic momentum equation for proton dPp dPz Ee edt qdt vz Pp p m p c, Pz z mz c z , z c z 1 m p qz 2 p mz e 2 1/ 2 5. Heavy ion acceleration and quark-gluon plasma Kinetic energy for heavy ion scaled from proton E z z 1mz c 2 ( 1 p2 2 z 2 2 ( 1 p 2 1) Az m p c , Az m p c 2 0.938GeV m 2p q z2 mz2 e 2 1)mz c 2 5. Heavy ion acceleration and quark-gluon plasma If proton kinetic energy reaches 100GeV (laser intensity about 1024w/cm2), and z/A~1/2, then Ez 50 Az GeV It means that in the frame of center of mass, zparticle colliding with kinetic energy 100AGeV may generate QGP. During the collision of two beams, the number of reaction with cross section is N N i2 / s 2 1010 / cm 2 106 , 10 24 cm 2 Where s is the beam sectional area 6. Conclusions and discussions 1. Charged particle accelerations in PW laser interaction with matters have extensively investigated, to understand mechanism is challenging. Now only the PW lasers of x100J/0.5ps is used for experiments, numerical simulations are limited by computer capability. Today kinetic energy~ GeV is possibly gained. 2. Due to advancing the study of fast ignition of inertial fusion driven by PW laser, based on present-day CPA technology, to obtain PW laser intensity over 1024w/cm2 is confident if tens beams are used and each beam has 2kJ/1 ps and the focused spot ~2 m . It means that there are possibility to design QGP experiment and to experimentally explore many important phenomena occurring in astrophysics in near future. Thanks