1. INTRODUCTION
For relativistic intensities of a main subpicosecond pulse, even high-contrast beams can produce plasma on a target surface due to a long nanosecond and picosecond prepulses impact, which results in target surface modifications before the main pulse action, and influences the subpicosecond pulse interaction with the target extremely (Povarnitsyn et al., Reference Povarnitsyn, Andreev, Levashov, Khishchenko and Rosmej2012b, Reference Povarnitsyn, Andreev, Levashov, Khishchenko, Kim, Novikov and Rosmej2013; Esirkepov et al., Reference Esirkepov, Koga, Sunahara, Morita, Nishikino, Kageyama, Nagatomo, Nishihara, Sagisaka, Kotaki, Nakamura, Fukuda, Okada, Pirozhkov, Yogo, Nishiuchi, Kiriyama, Kondo, Kando and Bulanov2014). In this paper, the generation of hot electrons at grazing incidence of a subpicosecond intense laser pulse onto a plane solid target is analyzed for the parameters of the petawatt high-energy laser for heavy ion experiments (PHELIX) (Bagnoud et al., Reference Bagnoud, Aurand, Blazevic, Borneis, Bruske, Ecker, Eisenbarth, Fils, Frank, Gaul, Goette, Haefner, Hahn, Harres, Heuck, Hochhaus, Hoffmann, Javorková, Kluge, Kuehl, Kunzer, Kreutz, Merz-Mantwill, Neumayer, Onkels, Reemts, Rosmej, Roth, Stoehlker, Tauschwitz, Zielbauer, Zimmer and Witte2010; Wagner et al., Reference Wagner, Bedacht, Ortner, Roth, Tauschwitz, Zielbauer and Bagnoud2014a) using three-dimensional (3D) particle-in-cell (PIC) modeling (Pukhov, Reference Pukhov1999) and a wide-range hydro modeling (Povarnitsyn et al., Reference Povarnitsyn, Andreev, Apfelbaum, Itina, Khishchenko, Kostenko, Levashov and Veysman2012a) of the preplasma expansion under the action of the laser prepulse. Elaboration of wide-range models of the laser–matter interaction is necessary for planning and interpretation of experiments carried out in view of different applications aimed for the development of secondary sources of high energy particles and hard radiation (Morace et al., Reference Morace, Fedeli, Batani, Baton, Beg, Hulin, Jarrott, Margarit, Nakai, Nakatsutsumi, Nicolai, Piovella, Wei, Vaisseau, Volpe and Santos2014; Brabetz et al., Reference Brabetz, Busold, Cowan, Deppert, Jahn, Kester, Roth, Schumacher and Bagnoud2015; Rusby et al., Reference Rusby, Wilson, Gray, Dance, Butler, MacLellan, Scott, Bagnoud, Zielbauer, McKenna and Neely2015; Vaisseau et al., Reference Vaisseau, Debayle, Honrubia, Hulin, Morace, Nicola, Sawada, Vauzour, Batani, Beg, Davies, Fedosejevs, Gray, Kemp, Kerr, Li, Link, McKenna, McLean, Mo, Patel, Park, Peebles, Rhee, Sorokovikova, Tikhonchuk, Volpe, Wei and Santos2015). Surface acceleration and transport of energetic electrons in intense laser–matter interactions at the grazing incidence were investigated experimentally for femtosecond laser pulses of hundreds mJ energy in (Wang et al., Reference Wang, Chen, Mao, Huang, Ma, Zhao, Zhang, Yan, Li, Ma, Ly, Lu, Wei, Sheng and Zhang2013; Mao et al., Reference Mao, Chen, Huang, Ma, Zhao, Li, Yan, Ma, Aeschlimann, Wei and Zhang2015) and for hundred joule subpicosecond laser pulses of the laser system PHELIX in paper (Gray et al., Reference Gray, Yuan, Carroll, Brenner, Coury, Quinn, Tresca, Zielbauer, Aurand, Bagnoud, Fils, KГјhl, Lin, Li, Li, Roth, Neely and McKenna2011).
For different laser systems the contrast of a nanosecond prepulse of amplified spontaneous emission (ASE) can vary within wide limits from 10−6 to 10−12 and higher, when plasma mirror focusing is used. The normal ASE contrast (or pedestal) is between 10−6 and 10−7, if no special measures are taken. A typical time structure of the petawatt class laser pulse is shown in Figure 4 of (Wagner et al., Reference Wagner, João, Fils, Gottschall, Hein, Körner, Limpert, Roth, Stöhlker and Bagnoud2014b), where the pulse shape of the PHELIX laser at the first harmonic, λ0 = 1.053 µm, is shown for different parameters of the contrast boosting module. For simulation of the laser–matter interaction at non-relativistic prepulse intensities, we have elaborated and used the two-temperature single-fluid radiation hydrodynamic model (Povarnitsyn et al., Reference Povarnitsyn, Andreev, Apfelbaum, Itina, Khishchenko, Kostenko, Levashov and Veysman2012a, Reference Povarnitsyn, Andreev, Levashov, Khishchenko, Kim, Novikov and Rosmej2013). This wide-range model describes laser energy absorption, electron–ion coupling and two-temperature effects, radiation transport, thermodynamic properties of materials, and ionization from normal conditions at room temperature to weakly non-ideal high-temperature plasma. Using the model we have studied pump-probe experiments (Povarnitsyn et al., Reference Povarnitsyn, Andreev, Apfelbaum, Itina, Khishchenko, Kostenko, Levashov and Veysman2012a) as well as the action of a nanosecond prepulse on thin films (Povarnitsyn et al., Reference Povarnitsyn, Andreev, Levashov, Khishchenko and Rosmej2012b, Reference Povarnitsyn, Andreev, Levashov, Khishchenko, Kim, Novikov and Rosmej2013). As opposed to the Radiative Arbitrary Lagrangian–Eulerian Fluid dynamics in two dimensions code (Ortner et al., Reference Ortner, Faik, Schumacher, Basko, Blazevic, Busold, Bedacht, Cayzac, Frank, Kraus, Rienecker, Schaumann, Tauschwitz, Wagner and Roth2015), in our model, the laser absorption is described using the wave equation for the laser pulse electric field.
This paper is organized as follows. Preplasma formation under the action of different contrasts prepulses is modeled and described in Section 2. The results of 3D PIC modeling of the electron acceleration by the main subpicosecond relativistic-intense laser pulse (with parameters typical for the PHELIX laser system at the first harmonic, λ0 = 1.053 µm) in the plasma produced by the prepulse are presented in Section 3. Discussion and conclusion are summarized in Section 4.
2. PREPLASMA FORMATION UNDER THE ACTION OF DIFFERENT PREPULSE CONTRASTS
To describe plasma corona formation under the action of different intensity prepulses, the 1D version (Povarnitsyn et al., Reference Povarnitsyn, Andreev, Levashov, Khishchenko, Kim, Novikov and Rosmej2013) of the HELIO2D code (Andreev et al., Reference Andreev, Povarnitsyn, Veysman, Faenov, Levashov, Khishchenko, Pikuz, Magunov, Rosmej, Blazevic, Pelka, Schaumann, Schollmeier and Roth2015) was used, which takes into account 1D hydrodynamic motion of matter, laser energy absorption, two-temperature non-equilibrium states for electron and ion subsystems, electron thermal conductivity, and radiation transport in diffusion approximation. The evolution of material parameters is described using the conservation of mass, momentum, and energy of electron and ion subsystems in a single-fluid two-temperature Lagrangian form.
2.1. Picosecond laser prepulse
While a nanosecond ASE prepulse can be substantially reduced by different measures, the prepulse emission on the timescale of a few tens of picoseconds is practically always present [see Fig. 4 of (Wagner et al., Reference Wagner, João, Fils, Gottschall, Hein, Körner, Limpert, Roth, Stöhlker and Bagnoud2014b)]. The importance of the multi-picosecond target dynamics in relativistic laser–matter interactions was recently emphasized in a publication (Schollmeier et al., Reference Schollmeier, Sefkow, Geissel, Arefiev, Flippo, Gaillard, Johnson, Kimmel, Offermann, Rambo, Schwarz and Shimada2015), where it was shown that inclusion of realistic temporal laser pulse profiles in modeling is necessary for the correct description of the laser energy conversion to hot electrons.
In our modeling of the plasma formation, we analyzed firstly the bulk Al target heating by the PHELIX picosecond prepulse only during the time interval (−100, −5) ps, as shown in Figure 1 for high contrast level ~10−10 at time less than −100 ps (zero time moment corresponds to the maximum of the laser pulse intensity).
The electron density distribution at t = −5 ps is shown in Figure 2 for the P-polarized laser pulse with the angle of incidence 80° and maximum intensity 4 × 1019 W/cm2. For electron densities less than, or about the density of the reflection point y r, the density profile can be well approximated by the rarefaction wave exponent with a characteristic scale length L r = 1.8 µm:
${\rm where \,{\it n}_{{\rm e,r}}} \equiv {n_{\rm e}}({y_{\rm r}}) = {n_{{\rm cr}}}\mathop {\cos} \nolimits^2 {\rm \theta} \!\approx\! 0.03 \times {n_{{\rm cr}}} \!\approx\! 3 \times {10^{19}}{\rm c}{{\rm m}^{ - 3}}$ for the angle of incidence θ = 80° and the laser wavelength λ0 = 1.053 µm (${n_{{\rm cr}}} = {\rm \omega}_0^2 {m_{\rm e}}/4{\rm \pi} {e^2}$ is the critical density for the laser frequency ω0 = 2πc/λ0). Here and hereinafter the electron plasma density is in the centimetre-gram-second system of units, while the scale length is in micrometers. The sum of distribution Eq. (1) and two high gradient exponential density profiles with the scale lengths of 0.45 and 0.05 µm at the densities 1022 and 1023 cm−3, respectively, reproduces quite well the total density profile of plasma corona obtained in simulation (see empty green circles in Fig. 2).
This three-exponential electron density profile of the plasma produced by the prepulse was used for modeling of the electron acceleration by the main picosecond laser pulse with a high contrast nanosecond ASE pedestal (of the level ≤10−11 when its influence can be neglected and only the picosecond prepulse can produce plasma before the main pulse action).
2.2. Nanosecond ASE pedestals
The influence of the 1 ns ASE pedestal (which acts before −100 ps, see Fig. 1) on the preplasma electron density distribution was investigated for the pedestal intensities in the range of 109–4 × 1011 W/cm2 for the same main laser pulse parameters (P-polarization, angle of incidence 80°, and maximum intensity 4 × 1019 W/cm2) that corresponds to the pedestal contrast levels in the range 2.5 × 10−11–10−8. All over these pedestal intensities, for the electron densities less and about the reflection point y r [${n_{\rm e}}({y_{\rm r}}) = {n_{{\rm cr}}}\mathop {\cos} \nolimits^2 {\rm \theta} \approx 3 \times {10^{19}}\;{\rm c}{{\rm m}^{ - 3}}$] the density profile can be well approximated by the rarefaction wave exponent (1) with the characteristic scale length L r in the range of 2–40 µm (see Fig. 3). The reflection point position y r demonstrates the plasma propagation as a function of the pedestal intensity (see Fig. 3).
These modeling results evidently show that even at a rather high contrast of the laser pulse pedestal of the order of 10−10 and a nanosecond duration, the characteristic scale length of the produced preplasma can be increased two times (L r = 3.6 µm) before the main short laser pulse action. For a lower contrast of the laser pulse pedestal in the range 10−9–10−8 (and also for smaller angles of laser incidence), the characteristic scale length of the prepulse produced plasma can increase substantially and reach tens of microns as shown in Figure 3.
The exponential electron density profiles of the prepulse produced plasma with a characteristic scale length from L r ≈ 2÷4 to 30 µm near the reflection point were used for PIC modeling of the electron acceleration by the main subpicosecond laser pulse with different contrast levels of the nanosecond ASE pedestal.
3. LASER-PLASMA ELECTRON ACCELERATION
PIC simulations were carried out with the 3D PIC code Virtual Laser Plasma Laboratory (Pukhov, Reference Pukhov1999). The geometry of interaction is shown in Figure 4.
The density profiles obtained by the wide-range hydro modeling of the preplasma expansion under the action of the laser prepulse were attached at y ≥ 0 to the homogeneous plasma slab with the electron density of 100 × n cr and thickness of 5 µm over the OY-axis [y ∈ ( − 5, 0) μm, see Fig. 4]. The simulation box had the sizes of 400 µm along the OX-axis and 80 µm along the OZ-axis. The size along the OY-axis was varied from 90 to 230 µm for various preplasma density profiles to get the reflection point y r inside the simulation box far enough from the boundaries. Cells with sizes 0.05 × 0.5 × 0.5 µm3 and four particles per cell for the electrons were used together with immobile ions which produced neutralizing background.
The main P-polarized laser pulse with the Gaussian envelope in time and space, λ0 = 1 µm, the full width at half maximum (FWHM) pulse duration 400 fs and energy 120 J was focused in the FWHM spot size of 25 µm with the angle of incidence 80° and maximum intensity 4 × 1019 W/cm2. Initially, at t = 0, the center of the laser pulse was far enough from the target at x 0 = −200 µm, z 0 = 40 µm, and y 0 was varied so that the pulse reached the reflection point y r at the middle of the x-length of the simulation box (at x ≈ 200 µm).
Figure 5 shows the energy spectra of accelerated electrons for the initial density scale lengths L r = 1.8 and 3.6 µm, typical for the contrast of the laser pulse nanosecond pedestal from 10−11 to 10−10. The spectrum with a hot temperature T h = 2.3 MeV predicted by the ponderomotive electron energy at a peak laser intensity (Wilks et al., Reference Wilks, Kruer, Tabak and Langdon1992) is shown also by the dotted line in Figure 5 for the coefficient of transformation of the laser energy to the hot electrons energy η = 0.07. With the increase in L r within a few micrometers the number of accelerated electrons drops for the energies higher than 30 MeV.
The lower contrast nanosecond ASE pedestal of the laser pulse can create longer density scales of the preplasma with L r ≥ 10 µm (see Fig. 3). In this case, the accelerating mechanism changes and the maximum energy of accelerated electrons can reach hundreds of MeV. The dependences of spectra of accelerated electrons on the laser pulse polarization and the angle of incidence are illustrated in Figure 6 for the fixed initial density scale length L r = 10 µm.
With the increase of the characteristic density scale length, the maximum energy of accelerated electrons grows up to about 300 MeV for the density scale length L r = 20 µm (at the expense of some decrease of the number of particles for the energies less than 50 MeV in comparison with a longer density scale length 30 µm, see Fig. 7).
Figure 8 illustrates qualitatively different angular distributions of accelerated electrons for different scale lengths formed by different contrast laser prepulses. For the preplasma scale length L r = 20 µm, which can be produced by the nanosecond ASE pedestal of an intensity about 1011 W/cm2 (see Fig. 3), accelerated electrons propagate at a small angle to the target surface, and the width of the angular distribution decreases for higher electron energies (upper plots of Fig. 8). While for a lower level of the laser pulse nanosecond ASE pedestal (of intensity less than 109 W/cm2, when the preplasma scale length L r = 1.8 µm), there are two jets of accelerated electrons propagating outward and inside the target with the angle (relative to the target surface) about the angle of propagation of the reflected laser pulse (lower plots of Fig. 8).
4. DISCUSSION AND CONCLUSIONS
Different energy spectra and angle distributions of hot electrons at ten times different preplasma scale lengths L r = 1.8 and 20 µm (see Figs 5, 7, and 8) indicate different mechanisms of the electron acceleration in the plasma corona. In the case of sharp (short scale length) plasma density gradients, produced quasi-static electric and magnetic fields are significant for generation and transport of high energy electrons along the surface of a solid target irradiated by high power laser pulses. The importance of quasi-static fields in the electron acceleration by a self-channeled relativistic-intense laser pulse was shown in paper (Pukhov et al., Reference Pukhov, Sheng and Meyer-ter Vehn1999). The mechanism and conditions for the formation of quasi-static surface fields at oblique incidence of a short intense laser pulse onto a solid target with a short scale length preplasma corona were analyzed in papers (Nakamura et al., Reference Nakamura, Kato, Nagatomo and Mima2004, Reference Nakamura, Mima, Sakagami and Johzaki2007). In full agreement with 2D PIC simulation results of (Nakamura et al., Reference Nakamura, Mima, Sakagami and Johzaki2007) (see Fig. 3 of this paper), the structure of quasi-static electric and magnetic fields obtained in our 3D PIC modeling (shown in Figure 9 for the preplasma scale length L r = 1.8 µm) indicates the formation of the focusing electric and magnetic fields reflecting electrons towards the vacuum. It should be noted that the enhanced transverse momentum of accelerated electrons (see Fig. 8 for the preplasma scale lengths L r = 1.8 µm), which exceeds substantially the normalized vector potential of the laser pulse, clearly indicates the resonant direct laser acceleration with assistance of quasi-static electric and magnetic fields (Pukhov et al., Reference Pukhov, Sheng and Meyer-ter Vehn1999).
A relatively low contrast nanosecond pedestal of the laser pulse can produce longer preplasma corona extended to tens of microns with density scales of the order or in excess of the laser spot size. In this case the mechanism of the laser acceleration along the target surface can be attributed to stochastic electron acceleration in plasma waves driven by an intense laser pulse at grazing incidence [see (Bochkarev et al., Reference Bochkarev, Brantov, Bychenkov, Torshin, Kovalev, Baidin and Lykov2014) and references cited therein]. Plasma waves in subcritical plasma are excited by a subpicosecond laser pulse with the duration much longer than the plasma wave period in the process of the pulse self-modulation (Antonsen & Mora, Reference Antonsen and M. Mora1993; Krall et al., Reference Krall, Ting, Esarey and Sprangle1993; Andreev et al., Reference Andreev, Gorbunov, Kirsanov, Pogosova and Sakharov1996, Reference Andreev, Gorbunov, Kirsanov, Pogosova and Ramazashvili1992). The self-modulation instability develops from the front of the laser pulse and saturates due to the plasma wave breaking. Fourier spectra of the longitudinal electric field e x ≡ |e| E x/mcω0 in the regions x ∈ (0, 200) μm and x ∈ (200, 400) μm, where the rear and front parts of the laser pulse are situated at ct = 200 µm, are shown in Figure 10(a) and 10(b), respectively, for the preplasma scale length L r = 20 µm at different distances from the initial target surface.
The enhanced Fourier-component on the right plot of Figure 10 in the spectral range $k/{k_0} \cong 0.1 \div 0.2$ (k 0 = ω0/c) reflects the excitation of plasma waves at plasma densities ${n_{\rm e}}/{n_{{\rm cr}}} \cong (1 \div 3) \times {10^{ - 2}}$ that is just about and below the unperturbed laser reflection point (y r ≈ 20 µm) for the angle of incidence 80°. The absence of these spectral lines in the left plot of Figure 10 (for the rear part of the laser pulse) indicates the saturation of self-modulation instability and transmission of the excited plasma waves energy to accelerated electrons.
Angular distributions of fast electrons emitted from intense laser–solid interactions were investigated in experiments at the PHELIX laser system at Gesellschaft fur Schwerionenforschung, Darmstadt for different angles of laser incidence (Gray et al., Reference Gray, Yuan, Carroll, Brenner, Coury, Quinn, Tresca, Zielbauer, Aurand, Bagnoud, Fils, KГјhl, Lin, Li, Li, Roth, Neely and McKenna2011). In these experiments the intensity contrast up to 50 ps prior to the peak of the pulse was about 10−6, that corresponds to the long scale plasma corona of tens of microns (see Fig. 3, L r). The measured angular distributions of energetic electrons for the laser incidence angle 80° is in good agreement with the modeling result shown in the upper plots of Figure 8.
In conclusion, preplasma formation under the action of different contrast prepulses is modeled and described using the wide-range two-temperature hydrodynamic model. The preplasma density profiles for different contrast ratios of the nanosecond pedestal are found and used as the initial density distributions in 3D PIC simulations of electron acceleration by the main P-polarized laser pulse.
The generation of hot electrons at the grazing incidence of a subpicosecond relativistic-intense laser pulse onto the plane solid target is analyzed for the parameters typical for petawatt class laser systems. Table 1 summarizes the parameters of electrons accelerated to high energies for two typical scale lengths of the preplasma density L r = 1.8 and 20 µm. For the grazing incidence of the laser pulse, the substantial increase of the characteristic energy, number, and collimation of electrons accelerated along the target surface is demonstrated (see Figs 5–7) in comparison with the ponderomotive scaling of laser–target interaction (Wilks et al., Reference Wilks, Kruer, Tabak and Langdon1992; Chen et al., Reference Chen, Wilks, Kruer, Patel and Shepherd2009).
ACKNOWLEDGMENTS
This work was supported by the Russian Science Foundation grant 14-50-00124.