2.1. Setup

The experiments were conducted at the Los Alamos National Laboratory using Trident's (Batha et al., Reference Batha, Aragonez, Archuleta, Archuleta, Benage, Cobble, Cowan, Fatherley, Flippo, Gautier, Gonzales, Greenfield, Hegelich, Hurry, Johnson, Kline, Letzring, Loomis, Lopez, Luo, Montgomery, Oertel, Paisley, Reid, Sanchez, Seifter, Shimada and Workman2008) short-pulse arm of 600 fs with 80 J of energy on-target at a wavelength of 1.053 µm. High temporal laser contrast of 10⁻⁷ at −4 ps enables interaction of the peak pulse with a highly overdense target even for nm-thicknesses. The on-target intensity has been controlled using different off-axis parabolic (OAP) mirrors with focal parameters F/8, F/3, and F/1.5 (as F/N with N = f/D, where f is the focal length and D the diameter of the laser beam). The resulting spot diameter is proportional to Nλ with λ the laser wavelength. Figure 1 shows images of the focus for all three OAPs in panels (b)–(d) with equal frame size. The diameters have been measured to be 13.8 µm (F/8), 7.9 µm (F/3) and 3.4 µm (F/1.5) with an encircled energy of 50% as depicted in Figure 1(e). These yield time averaged intensities I ₀ of 9.4 × 10¹⁹, 2.9 × 10²⁰, and 1.7 × 10²¹ W/cm², respectively, as shown in Figure 1(a) or normalized laser amplitudes $a_0 = \sqrt {I_0 {\rm (W}/{\rm cm}^2 )\;\ast\;{\rm \lambda} ^2 {\rm (\mu m)}/1.37 \times 10^{18}} $ of 8.6, 14.7, and 34.5, respectively.

Fig. 1. (a) Measured intensity as a function of distance to the peak for three OAPs with F/number of F/8, F/3 and F1.5. 16 bit images of the laser foci with equal frame size are shown in (b)–(d). The spot diameters are 13.8 µm (F/8), 7.9 µm (F/3), and 3.4 µm (F/1.5) with a 50% encircled energy criterion as depicted in (e).

Ion spectra have been measured using an ion wide angle spectrometer (iWASP), as described by Jung et al. (Reference Jung, Hrlein, Gautier, Letzring, Kiefer, Allinger, Albright, Shah, Palaniyappan, Yin, Fernndez, Habs and Hegelich2011, Reference Jung, Senje, McCormack, Yin, Albright, Letzring, Gautier, Dromey, Toncian, Fernandez, Zepf and Hegelich2015). The iWASP is based on particle deflection in a magnetic field of order of 0.5 T and a 30 µm slit aperture to measure the spectra angularly resolved in one plane, covering a range of about 25°. Species separation is achieved by use of the vastly different stopping powers of carbon ions and protons in a stacked detector consisting of a 32 µm Al layer (for laser light protection), followed by a 1 mm thick CR39 (Fleischer et al., Reference Fleischer, Price and Walker1965) and a BAS-TR image plate (IP) (Mancic et al., Reference Mancic, Fuchs, Antici, Gaillard and Audebert2008; Paterson et al., Reference Paterson, Clarke, Woolsey and Gregori2008). The CR39 detects carbon ions above 33 MeV (the energy needed to pass the Al layer); protons above 11 MeV leave no visible tracks on the CR39 (unless etched for several hours); here, typical etching times of 10 min were applied. The IP is used to detect protons above 11 MeV passing through the CR39 in front of the IP. It should be noted that carbon ions above 230 MeV are not stopped within the CR39, though they still leave visible tracks. These will also be detected on the IP. For the ion energies observed during this experiment, the detector stack and the dispersion of the iWASP magnet gave no overlap of the carbon and proton signal on either the CR39 or the IP (see Jung et al., Reference Jung, Senje, McCormack, Yin, Albright, Letzring, Gautier, Dromey, Toncian, Fernandez, Zepf and Hegelich2015 for details). The energy resolution (lower instrument limit) at 80 MeV/amu for protons and carbon C⁶⁺ ions is approximately ±3 and ±6%, respectively. The advantage of using the iWASP is its large solid angle of >0.1 msr, which is 3–5 orders of magnitude larger than in conventional Thomson parabolas and results in much higher precision measurements of the absolute peak ion energy. This is important especially for ion acceleration mechanisms where maximum energies are emitted off-axis rather than on-axis. For the BOA mechanism it has recently been demonstrated in simulations and experimentally (Yin et al., Reference Yin, Albright, Bowers, Jung, Fernández and Hegelich2011a; Jung et al., Reference Jung, Albright, Yin, Gautier, Shah, Palaniyappan, Letzring, Dromey, Wu, Shimada, Johnson, Roth, Fernandez, Habs and Hegelich2013a) that maximum energies are in fact emitted off-axis, demanding a large solid angle for accurate measurements.

Thin, free-standing, artificially grown diamond foils (Applied Diamond, Inc.) with density of ~3 g/ml have been used as target material. Thicknesses range from 30 nm to 5 µm; the bulk proton concentration is naturally very low and hydrogen contamination on the surface is the main source of protons.

2.2. The RITA regime

In laser–matter interactions with a normalized laser amplitude a ₀ > 1, electrons gain relativistic quiver energies in the laser field. At these intensities, if parameters are chosen accordingly, the target undergoes a phase of relativistic-induced transparency during the peak laser pulse interaction. Relativistic transparency defines a special state of the plasma, where it is classically overdense, yet relativistically underdense. Classically, that is, neglecting relativistic effects, the normalized electron density N = n _e/n _cr > 1 with the critical electron density $n_{{\rm cr}} = m_{\rm e} {\rm \omega} _{\rm \lambda} ^2 /(4{\rm \pi} e^2 )$ with ω_λ the laser frequency. Accounting for the relativistic electron momentum increase by the Lorentz factor γ_e, however, N′ ≈ N/γ_e ≤ 1 and the plasma is relativistically transparent. Note that our condition for the onset of transparency is based on the electron thermal Lorentz factor γ_e and not on the laser intensity a ₀ as reported by Vshivkov et al. (Reference Vshivkov, Naumova, Pegoraro and Bulanov1998); the former condition is found to be in good agreement with our PIC simulations in the RITA regime and stems from the significant target heating that occurs prior to the relativistic transparency. Using the Trident laser we found that with intensities exceeding 5 × 10¹⁹ W/cm², diamond targets with thickness between 200 to 600 nm turn relativistically transparent during the peak laser interaction as recently reported by Palaniyappan et al. (Reference Palaniyappan, Hegelich, Wu, Jung, Gautier, Yin, Albright, Johnson, Shimada, Letzring, Offermann, Ren, Huang, Hörlein, Dromey, Fernandez and Shah2012).

When the plasma undergoes such a phase of relativistic transparency during the peak pulse interaction, efficient acceleration via the BOA mechanism is possible (Albright et al., Reference Albright, Yin, Bowers, Hegelich, Flippo, Kwan and Fernandez2007). When the target is relativistically transparent, electrons are accelerated toward the rear of the target in the intense laser field, which sets up a strong longitudinal electric field that co-moves with the ions. The time at which the target becomes relativistically transparent is typically referred to as t ₁ in the BOA mechanism. Before that time, the target is classically overdense with N′ >N′/γ_e>1 and acceleration of ions occurs in an electric field E _x determined by the distribution of hot electrons produced at the front side of the target. In PIC simulations, ions gain only about 10% of their final kinetic energy before t ₁ (Yin et al., Reference Yin, Albright, Jung, Shah, Palaniyappan, Bowers, Henig, Fernndez and Hegelich2011b). After time t ₁, when the target is relativistically transparent, the laser continuously imparts forward momentum to the electrons, which couple to the ions, thus accelerating them to extreme energies, which may exceed 100 MeV/amu (Yin et al., Reference Yin, Albright, Jung, Shah, Palaniyappan, Bowers, Henig, Fernndez and Hegelich2011b; Jung et al., Reference Jung, Yin, Gautier, Wu, Letzring, Dromey, Shah, Palaniyappan, Shimada, Johnson, Schreiber, Habs, Fernández, Hegelich and Albright2013d; Hegelich et al., Reference Hegelich, Jung, Albright, Cheung, Dromey, Gautier, Hamilton, Letzring, Munchhausen, Palaniyappan, Shah, Wu, Yin and Fernández2013). When the target expands to become classically underdense (with N ≤ 1) at time t ₂, acceleration of ions decreases significantly due to the low coupling efficiency of laser light into the low-density plasma. In contrast, the target stays classically and relativistically overdense during acceleration in the TNSA and RPA regimes. When transparency occurs, the plasma reflectivity R(ω) drops substantially, decreasing the efficiency of energy transfer through the radiation pressure significantly (Macchi et al., Reference Macchi, Veghini, Liseykina and Pegoraro2010).

For a fixed set of laser parameters, that is, contrast, pulse duration, laser energy, and spot diameter, these times are strongly dependent on the target thickness and density. If the target is too thin, t ₂ will be reached before the arrival of the peak pulse and energy transfer is significantly reduced. If the target is too thick, t ₁ will come after the peak pulse arrival or not at all for very thick targets. Thus, optimal ion acceleration is obtained when the peak pulse interacts with the target between t ₁ and t ₂. A plausible explanation for how efficient energy transfer occurs during the relativistic transparency was reported by Albright et al. (Reference Albright, Yin, Bowers, Hegelich, Flippo, Kwan and Fernandez2007), who proposed that a relativistic, drifting electron population driven by the laser induces a beam–plasma instability. This can generate an unstable plasma “quasi-mode” characterized by the growth of large-amplitude, longitudinal electric fields that co-propagate with and accelerating the ions. It has been found in this report that the observed beam–plasma instability follows the dynamics of the Buneman instability that has been studied extensively in non-relativistic plasmas, including laboratory and space settings (Buneman Reference Buneman1959; Reitzel & Morales, Reference Reitzel and Morales1998).

3.1. Experimental results

In order to find the maximum possible energy at a given intensity, the optimum thickness needs to be determined. This is necessary as the dynamics of the plasma density evolution and thus the relativistic transparent phase strongly depend on the target and laser parameters. In particular, the laser contrast has a difficult to predict influence on these dynamics; premature heating of the target under the laser pedestal and the rising edge of the laser pulse lower the initial target density at the time the peak of the laser pulse arrives. Therefore, a full thickness scan has been conducted for each intensity to find the optimum thickness and maximum possible energy. Three thickness scans with on-target intensities ranging from 10¹⁹ to 10²¹ W/cm² have been performed. In Figure 2(a), typical maximum carbon C⁶⁺ energies are shown as a function of target thickness [red stars: ≈8 × 10¹⁹ W/cm² (a ₀ = 8), blue circles: ≈2 × 10²⁰ W/cm² (a ₀ = 13), and the green triangles: ≈10 × 10²¹ W/cm² (a ₀ = 29)]. The increasing scatter with increasing intensity is a result of the stronger fluctuations in the on-target intensities and stronger sensitivity to target alignment. This is mainly caused by the reduced Rayleigh length z _r of the laser focus, which is proportional to the aperture of the different focusing optics used to control the intensity and additionally by shot-to-shot fluctuations in the laser contrast, especially at higher intensities. The optimum thickness for each intensity has been estimated using standard peak fitting [solid lines in Fig. 2(a)]; it ranges from 75 to 175 nm for ≈8 × 10¹⁹ W/cm² with peak at 130 nm, from 100 to 300 nm for 2 × 10²⁰ W/cm² with peak at 230 nm and from 350 nm to past 550 nm for 1 × 10²¹ W/cm² with peak at 480 nm (where the latter fit has a higher uncertainty due to less data points and higher fluctuations). The peaks are shown in Figure 2(b) as a function of the normalized laser amplitude (black stars) overlaid with the experimental data points within the found optimum thickness ranges (red squares). In Figure 3(a), only the highest measured energies for each intensity are plotted (red stars) as a function of the normalized laser amplitude a ₀ (the actual on-shot intensity and a ₀ for each data point are time-averaged as derived from the on-shot measured pulse duration and on-target laser energy). We also added results published by Henig et al. (Reference Henig, Kiefer, Markey, Gautier, Flippo, Letzring, Johnson, Shimada, Yin, Albright, Bowers, Fernández, Rykovanov, Wu, Zepf, Jung, Liechtenstein, Schreiber, Habs and Hegelich2009a) for ion acceleration in the RITA regime, also performed on Trident but using plasma mirrors. For the intensities covered, the results have been fitted using a linear correlation between a ₀ and the maximum ion energy (red solid line) with E _max = 28(a ₀ − 0.7) MeV. (It should be noted that since we could only cover three intensities experimentally, power laws ranging from 0.2 to 1 show similar χ² confidences.)

Fig. 2. Left frame: Maximum carbon C⁶⁺ energies. Red stars are for intensities of ≈ 8 × 10¹⁹ W/cm² (a ₀ = 8) obtained with an F/8 OAP, the blue circles for ≈ 2 × 10²⁰ W/cm² (a ₀ = 13) obtained with the F/3 OPA (see also Jung et al., Reference Jung, Yin, Albright, Gautier, Letzring, Dromey, Yeung, Hörlein, Shah, Palaniyappan, Allinger, Schreiber, Bowers, Wu, Fernandez, Habs and Hegelich2013c) and the green triangles for ≈ 1 × 10²¹ W/cm² (a ₀ = 29) obtained with the F/1.5 OAP. Solid lines are fits using Giddings peak function to obtain the optimum thickness. Note that the increasing scatter with increasing intensity in the measured energies is a result of the stronger fluctuations in the on-target intensity and stronger sensitivity to target alignment due to the reduced Rayleigh length of the laser focus. Right frame: plot showing data points around the optimum thickness (light red square) as a function of the normalized laser amplitude a ₀. The black stars are the values obtained from the Giddings peak function fits from the left frame and the purple line is a plot of the optimum thickness calculated using the model presented in Eq. (2) using an adjusted initial intensity n′₀ of 350.

Fig. 3. Maximum carbon C⁶⁺ ion energies as a function of the normalized laser amplitude a ₀ using different final focusing optics with F-number F/8, F/3, and F/1.5 (red stars). Results for 2D (blue 2) and 3D (purple 3) simulations with parameters close to the experiment. Results from the analytic model using Trident parameters (green M) and a linear fit of the analytic results (green solid line).

3.2. PIC-simulations and analytical model

In order to verify our findings, we also performed several 2D simulations with parameters similar to the experiment and one large-scale 3D simulation to confirm that the salient BOA dynamics are contained in 2D. The simulations employ relativistic, electromagnetic, charge-conserving, PIC code VPIC (Bowers et al., Reference Bowers, Albright, Yin, Bergen and Kwan2008). Figure 3(b) includes a large body of simulations where laser energy, optical f/# (focal spot size), target density, and pulse duration were varied. Together, the simulations show a characteristic scaling of peak ion energy with a ₀ time-averaged over the interval from t ₁ to t ₂. The 2D simulations use a domain of 50 × 25 or 50 × 50 µm² in the (x, z) plane (the target transverse width is 25 or 50 µm). The laser pulse is polarized along y, propagates along x, and has a time-varying intensity profile $I(t) = I_0 \mathop {\sin} \nolimits^2 (t{\rm \pi} /{\rm \tau} )$, where τ/2 = 540 fs [or 700 fs is the full-width at half-maximum (FWHM)]. The central laser wavelength is 1054 nm, as in the experiments. The laser electric field has a 2D-Gaussian spatial profile with best focus at the target surface, where $E_y \approx \exp {\kern 1pt} ( - z^2 /w^2 )$ and w = 4–5.12 µm. Solid density C⁶⁺ (diamond-like) targets at n _e/n _cr = 660 (and 821) with 2.2 g/cm³ (and 2.8 g/cm³); $n_{{\rm cr}} = m_{\rm e} {\rm \omega} _0^2 /4{\rm \pi} e^2 $ is the critical density in CGS units and ω₀ is the laser frequency) were employed with 5% (and 20%) protons in number density. The density is initially a constant-density slab profile. Both 2D and 3D (more details can be found in Yin et al. (Reference Yin, Albright, Bowers, Jung, Fernández and Hegelich2011a, Reference Yin, Albright, Jung, Shah, Palaniyappan, Bowers, Henig, Fernndez and Hegelichb) simulations retain the Debye-length-scale physics throughout the duration of the simulation. The size of the simulation box was chosen to give optimum resolution in the RITA regime and the BOA mechanism where the acceleration region is localized to within the center of the target and does not depend sensitively on accurately capturing the electron dynamics outside this region (Yin et al., Reference Yin, Albright, Jung, Shah, Palaniyappan, Bowers, Henig, Fernndez and Hegelich2011b).

The results are shown in Figure 3(b) where 2D simulations are denoted by “2” and the 3D simulation by “3”. A linear regression of the PIC results for the covered range from 1 to 50 gives E _max = 33(a ₀ − 0.8) MeV (blue solid line). The results are in good agreement with our experimental data as shown in Figure 3(c).

3.3. Analytic model

In order to develop an analytic expression for the scaling law and the optimum thickness, we apply the model published by Yan et al. (Reference Yan, Tajima, Hegelich, Yin and Habs2010), which is based on the electron reflexing model by Mako and Tajima (Reference Mako and Tajima1984). In this model, acceleration occurs between the onset of the relativistic transparency at time t ₁ when the target has turned relativistically transparent (when the density has decreased to N′ = N/γ ≤ 1) and the time t ₂ when the target has turned classically underdense (N ≤ 1 and N′ ≪ 1). The time t ₁ is calculated via an 1D expansion of the target as t ₁ = (12/π²)^1/4 [Nτd/(a ₀C _s)]^1/2, with d the target thickness and ion sound speed C _s ≈ q _im _ec ²a ₀/m _i and charge state q _i. The time t ₂ is derived from a 3D isospheric expansion starting at t ₁ with t ₂ = t ₁ + Nd(γ^1/3 − 1)/[γC _ssin (ωt ₁)] and ω the laser frequency. The maximum ion energy E _max is calculated through the response of the (non-relativistic) ions to the electrostatic field, that is, to the time-averaged electron energy $E_0 = m_{\rm e} c^2 /\Delta t\int [(a^2 (t') + 1)^{1/2} - 1]dt'$ due to the ponderomotive force and the duration Δt = t ₂ − t ₁ of the relativistic transparent phase with $E_{\max} = (2{\rm \alpha} + 1)q_{\rm i} \bar E_0 $$\{ [1 + {\rm \omega} _{\rm p} (t_2 - t_1 )]^{1/2{\rm \alpha} + 1} - 1\} $. The scaling factor α is a coherence parameter that describes how efficiently ions couple to the electrons; for a wide range of parameters α ≈ 3, provided 0.1 ≤ Nd/a ₀λ ≤ 10 [see Yan et al. (Reference Yan, Tajima, Hegelich, Yin and Habs2010)].

In Figure 3(b), E _max has been plotted for Trident parameters with different laser focus sizes [green circles, 80 J, τ_λ = 600 fs FWHM, a(t′) with a sin² temporal envelope]. This model matches the 2D and 3D-VPIC and experimental results.

Taking the ansatz that $E_{\max} \propto a_0 {\rm \tau} _{\rm \lambda} ^{\rm x} $, a parametric study over a large parameter range gives x = 0.28 and the following expression for the scaling:

(1)$$E_{\max} \approx 5{\rm \tau} _{\rm \lambda} ^{0.28} (a_0 - 1)\,{\rm MeV} \propto I_{\rm L}^{0.5} {\rm \tau} _{\rm \lambda} ^{0.28} $$

where τ_λ is in units of femtoseconds. In Figure 3(b), the scaling has been plotted using τ_λ = 600 fs. This yields for Trident-like parameters a maximum energy of E _max = 30(a ₀ − 1) MeV according to the analytical model. It is apparent that the expression only applies for relativistic laser intensities with a ₀ ≥ 1. The curve is in very good agreement with the simulations and the experimental data as shown in Figure 3(c). Using τ_λ = 45 fs and a ₀ = 5, the model yields E _max = 60 MeV, which is close to the maximum carbon energies observed in an experiment published by Steinke et al. (Reference Steinke, Henig, Schnrer, Sokollik, Nickles, Jung, Kiefer, Hrlein, Schreiber, Tajima, Yan, Hegelich, Meyer-ter Vehn, Sandner and Habs2010) (with a target thickness of 7 nm, basic conditions for relativistic transparency during the interaction are given for these parameters).

It should be noted here that this basic model only assumes a single species and charge and does not include any physics related to multi-species targets or ionization. In the model by Yan et al., the maximum energy is linearly dependent on the ion charge q _i, so that the leading factor 5 in Eq. (1) might be replaced with 5q _i/6. In that sense, the model is strictly applicable only to the species experiencing the BOA dynamics during the relativistic transparent phase of the interaction and acceleration in the co-moving electric field. For the targets used here, this does not apply to the (surface-)protons, as they are removed from the diamond targets long before the peak pulse interaction (Jung et al., Reference Jung, Albright, Yin, Gautier, Shah, Palaniyappan, Letzring, Dromey, Wu, Shimada, Johnson, Roth, Fernandez, Habs and Hegelich2013a, Reference Jung, Yin, Gautier, Wu, Letzring, Dromey, Shah, Palaniyappan, Shimada, Johnson, Schreiber, Habs, Fernández, Hegelich and Albrightd) due to “self-cleaning” (Yin et al., Reference Yin, Albright, Hegelich, Bowers, Flippo, Kwan and Fernandez2007). Data collected for proton acceleration from CH-plastic targets with a large bulk-proton concentration presented by Hegelich et al. (Reference Hegelich, Jung, Albright, Cheung, Dromey, Gautier, Hamilton, Letzring, Munchhausen, Palaniyappan, Shah, Wu, Yin and Fernández2013) support the scaling presented for protons here.

Applying the scaling law to a given set of laser parameters also requires that the optimum target thickness is used. We have used the same technique as above to derive an analytic expression for the optimum thickness (in units of nanometers) as

(2)$$\eqalign{d_{{\rm opt}} \approx 9.8 \times 10^{ - 10} I_{\rm L}^{13/24} {\rm \tau} _{\rm \lambda} {\rm (\,fs)}/N_0 \approx 6.7{\rm \tau} _{\rm \lambda} a_0^{13/12} /N_0 \approx a_0 {\rm \tau} _{\rm \lambda} /N_0}$$

A drawback of this expression is its dependency on the target density N ₀ that is present at the arrival of the peak pulse. Laser contrast is not included in the model and N ₀ is thus a free parameter. Setting N ₀ = 400 (half of the initial density) reproduces the experimentally observed optimum thicknesses for all three intensities. Using half the initial density for Steinke et al. (Reference Steinke, Henig, Schnrer, Sokollik, Nickles, Jung, Kiefer, Hrlein, Schreiber, Tajima, Yan, Hegelich, Meyer-ter Vehn, Sandner and Habs2010) with N ₀ = 250 in fact reproduces 7 nm as optimum thickness for their parameters.