3.1. Proton Spectra for 2ω Irradiation, Pitcher-Only

Starting with 2ω irradiation, Figure 2 compares proton spectra measured with TP1 and TP2 for a 1.2-μm-thick Mylar foil compared to a BN nanotube target. The BN nanotube target was 110 μm thick and had an average density of 0.55 g/cm³, which is 2–3 times lower than solid density. The plots show the proton spectra for a single shot, normalized to 1 J of laser energy.

Figure 2: Proton spectra for 2ω irradiation, Mylar foil vs. BN nanotube target. The proton spectra from front (a) and back side (b) of the 1.2-μm Mylar foil are nearly identical indicating TNSA on both sides of the target. The 100-μm-thick BN nanotube target results in more than double the maximum energy on the front side (c) and still ∼5 MeV from the rear side (d), suggesting that the laser is absorbed more efficiently due to the nanostructure of the BN nanotubes.

Figures 2(a) and 2(b) show the Mylar foil proton spectra at the front (laser irradiated) and back side, respectively. The spectra look nearly identical, confirming the high contrast of the laser pulse that leads to TNSA proton acceleration on both sides of the target [Reference Ceccotti, Levy and Popescu23]. The maximum proton energies are 4–5 MeV. The spectral shape can be described by

(6) $\begin{array}{}\frac{\text{d}N}{\text{d}E}=\frac{N_0}{E}\exp \left(\frac{-E}{k_B{T}_e}\right),\end{array}$

where N ₀ and k _B T _e are the fit parameters (orange lines). Except for Figure 2(c), N ₀ ≈ 10⁸ and k _B T _e ≈ 0.1 MeV. Using the filtered CR39 plates (positions A thru F), we confirm that the proton emission is strongly peaked in the target normal directions, as expected.

Figures 2(c) and 2(d) show the proton spectra for the 110-μm-thick BN nanotube target. Of striking difference is the front side proton spectrum, which reaches almost 10 MeV. Here, N ₀ ≈ 10⁷ and k _B T _e ≈ 0.5 MeV. The rear side spectrum is similar to the Mylar foil, even though the BN nanotube is 100 times thicker than the Mylar foil. The filtered CR39s measured about 100 times more particles along the target normal directions, as well as significant particle counts in all the measured off-normal directions. We interpret these findings as due to enhanced, volumetric absorption of the laser pulse compared to surface absorption for the foil target due to both the nanostructured surface and the overall reduced density.

3.2. Proton Spectra for 2ω vs. 1ω Irradiation, Pitcher-Only

After verifying that BN nanotubes lead to hotter proton spectra at high-contrast, 400-nm irradiation, we repeated a similar measurement using the fundamental wavelength and with higher laser energy. Figure 3(a) shows a direct comparison of Mylar foil and BN nanotube target backside proton spectra for 2ω irradiation, and Figure 3(b) the same for 1ω, for 30-μm BNNTs, and for a 7-μm Al foil. The spectra were measured by integrating over 10 shots (2ω, 20 shots for 1ω) for reproducibility. The plots show the processed proton spectra for a single shot, normalized to 1 J of laser energy.

Figure 3: Rear-side TP ion spectra (TNSA protons) show 10⁴ times more particles for 1ω vs. 2ω irradiation. The data show single-shot spectra, per 1 J of laser energy, by dividing the multishot integrated measurement by the number of shots and laser energy. (a) The 2ω spectra are very similar for both the Mylar foil and the BN nanotube target, despite the BN nanotube target being 100 times thicker. (b) The 1ω spectra exhibit about 100 times more protons at 1 MeV. Additionally, the BN nanotube target accelerated protons up to 20 MeV energy, about five times higher than the Al foil target.

The 2ω spectra are very similar for both the foil and the BN nanotube targets, despite the BN nanotube target being 100 times thicker. Compared to 2ω irradiation, the 1ω spectra exhibit about 100 times more protons at 1 MeV. Additionally, the BN nanotube target accelerated protons up to 20 MeV energy, about five times higher than the Al foil target. This finding supports the hypothesis that thinner BN nanotube targets outperform comparable foil targets as a proton source. The hundredfold higher particle numbers were not expected; as a result, the TP traces for the 1ω shots are saturated over large parts of the parabolic traces. The saturated parts were removed from the analysis and the spectrum was analyzed near the high and low energy ends of the trace where the dispersion in the TP was large enough to reduce the particle flux below saturation (low energies) or the particle numbers were low enough (high energies).

After plotting the extracted particle numbers from the TP traces, we fitted spectra using Equation (6) to determine the particle yields and slope.

For the 7-μm Al foil irradiated at 1ω, we compared the particle flux detected with CR39 #B and the TP trace. The particle count in this CR39 detector reached about 5 × 10⁸ protons/sr/J/shot behind the 75-μm Al filter, corresponding to protons with energies above 1.6 MeV. This filter thickness ensures that only protons were detected in the CR39. Alpha particles need ∼12 MeV and carbon or B, N ions need >60 MeV to penetrate the filter. The pit diameters behind this filter are all about 500 nm, in line with the expected proton pit diameters for our etch conditions. Integrating the TP spectrum for energies above 1.6 MeV results in a proton count of 3 × 10⁸ protons/sr/J/shot, giving confidence in our TP calibration. For comparison, the BN nanotube created about ten times more protons.

We did not field an imaging proton spectrometer such as, for example, a stack of radiochromic films [Reference Nurnberg, Schollmeier and Brambrink24, Reference Schollmeier, Geissel, Sefkow and Flippo25] to measure the full beam size or divergence angle. However, typically TNSA beams exhibit a cone angle of up to ±15° [Reference Nurnberg, Schollmeier and Brambrink24–Reference Prencipe, Metzkes-Ng and Pazzaglia28] for the lower energies, which contribute the most to the particle numbers. Assuming this value as an estimate for the proton beam divergence for both target types results in 4 × 10⁹ protons per shot for the Al foil and 4 × 10¹⁰ protons for the BN nanotube target. These yields are similar to the results from [Reference Prencipe, Metzkes-Ng and Pazzaglia28], who compared proton beam from thin foils to foam-coated thin foils. There, the foam-coating resulted in enhanced laser absorption and about four times higher proton yield than uncoated foils. Our results indicate that BN nanotube targets could yield even better absorption and more protons, potentially due to the nanostructures spanning the entire material. Even higher proton energies are expected from thinner BN nanotube targets [Reference Fuchs, Antici and d’Humieres29, Reference Schreiber, Bolton and Parodi30], but this was beyond the scope of this investigation.

3.3. Pitcher-Catcher Experiment at 1ω Irradiation

After having determined that BN nanotube targets irradiated at 1ω created the proton source with the highest particle numbers and energies, a pitcher-catcher experiment was performed where the proton beam was directed at a BN plate as described in Figure 1(b). The most striking results were that we measured significant nuclear activation during the postshot gamma spectroscopy, as well as a neutron time-of-flight signal, both of which are clear evidence for nuclear reactions.

3.4. Nuclear Activation

An example measurement is shown in Figure 4. The gamma spectrum is dominated by the 511 keV electron-positron annihilation peak, verifying the existence of positron emitters (in contrast to, e.g., excited nuclei from Bremsstrahlung photoexcitation). The second peak at about 250 keV is from backscattered 511 keV primary photons in the lead shielding nearby. The decay of the 511 keV peak was monitored in 5-minute integration intervals until it reached background levels. Prior to the measurements, the background counts were determined using the same integration time. Two gamma spectrometers on either side of the target frame were used in ∼1 cm distance to monitor an almost 4π solid angle. The detection efficiency of the NaI scintillator for 511 keV photons was estimated as 35% [Reference Cecil, Medley, Nieschmidt and Zweben20].

Figure 4: Postshot gamma spectroscopy of the pitcher-catcher shots. A strong peak at 511 keV is measured, verifying the existence of positron emitters (in contrast to, e.g., excited nuclei from photoexcitation). The second peak at about 250 keV is from backscattered 511 keV primary photons in the lead shielding nearby. The photograph in the inset shows one of the detectors inside of the lead housing with the top removed.

The activation results for the pitcher-catcher shots are plotted in Figure 5. The pitcher-only shots performed earlier did not produce any measurable activation above the background. Therefore, we can assume that the majority of the measured activation is from the BN catcher plate and not the primary source target. As discussed above and shown in Table 1, the most likely isotopes to be created are ¹¹ C, ¹³ N, and ¹⁸ F. The three decays were fitted to the measured data to obtain the partial contributions of each nuclide. The decay curves can be extrapolated to t ₀ when the last laser shot occurred to get the activity A right after the shots. The total activity A _total was 11.5 kBq after 30 shots. From the activity and the decay constant λ = ln (2)/τ, where τ is the half-life, the number of activated nuclei can be easily calculated as N = A/λ.

Figure 5: Pitcher-catcher nuclear activation measurements. (a) Each black data point shows the background-corrected counts as an average of the two spectrometer counts (shown in light-blue and light-green). Time zero corresponds to the time of the last laser shot on the targets. The dashed lines are the result of fitting the decays of ¹³ N, ¹¹ C, and ¹⁸ F to the data. Note the logarithmic ordinate. Details are given in the figure legend and the text. (b) is a zoomed view of the data at early times, on a linear scale, to better visualize that the ∼6.5% contribution of ¹³ N is needed to match the measurements.

The fit results are summarized in Table 2 and plotted with the dashed lines in Figure 5. The most abundant isotope is ¹¹ C, which is from protons fusing with ¹¹ B to create the ¹¹ C isotope and a neutron.

Table 2: Activation results for the pitcher-catcher shots after 30-shot integration.

Each column lists physical and fit parameters for the three discussed nuclei. N ₂ is the calculated number of nuclei based on the measured activity A. The last row is the same number, normalized per shot per 1 J of energy.

It is worthwhile to compare our results to earlier measurements by Labaune et al. [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2]. In [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2], the laser energy was about 10 J. Up to 500 Bq of nuclear activation was detected. Our laser delivered 14.3 J and created ∼400 Bq per shot, which is similarly efficient but does not require a secondary laser pulse to boost the activation levels. Unlike [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2], we see a clear contribution of ¹³ N to the measurements as shown in the zoomed view in Figure 5(b). At late times, ¹⁸ F appears with an activity of 3 Bq, about the same activity as measured in [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2]. However, the relative contributions of the three different isotopes are very different. In [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2], the ¹⁸ F isotope had a relative abundance of 0.6%, whereas our measurements yield an about 20x lower contribution. Reference [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2] interpreted the ¹⁸ F creation to be originated by alpha particles and a proof-of-concept that secondary reactions are possible. If that is true, the alpha particles should also create ¹³ N isotopes. The measurements in [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2] showed hints of ¹³ N creation but were not conclusive.

Our measurements show a clear evidence for ¹³ N isotopes, as well as ¹⁸ F. In the following, we calculate the expected number of isotopes assuming beam-target fusion reactions and using the 1ω BN nanotube target spectrum from Figure 3 as input. The number of reaction products N ₂ depends on the number of incoming projectiles N _projectile, target ion density n _target, cross section σ, and projectile range R:

(7) $\begin{array}{}{N}_2=N_{\text{projectile}}{n}_{\text{target}}\sigma R.\end{array}$

The projectile range R depends on the incoming projectile energy E ₀ and the ion-stopping power dE/dx. As the projectile slows down in the material, its energy is reduced and correspondingly the cross section changes. Therefore, the product σ R in Equation (7) is replaced by an integral over the cross section and stopping power to calculate N ₂ [Reference Giuffrida, Belloni and Margarone5]:

(8) $\begin{array}{}{N}_2=N_{\text{projectile}}{n}_{\text{target}}{\int }_0^{E_0}\sigma \left(E\right){\left(\frac{\text{d}E}{\text{d}x}\right)}^{-1}\text{d}E.\end{array}$

The stopping power was taken from the SRIM software package [Reference Ziegler, Biersack and Ziegler31], and the cross-sectional data were obtained via the Janis database [Reference Soppera, Bossant and Dupont12]. Taking the proton-boron fusion reaction ¹¹ B (p, α) 2α as an example, with the analytic cross section from [Reference Nevins and Swain32], an incoming proton energy of E ₀ = 1 MeV, and noting that this reaction creates three alpha particles per proton, we calculate a yield of 3.9 × 10⁻⁵ alpha particles per proton. The slight discrepancy to the efficiency obtained in [Reference Giuffrida, Belloni and Margarone5] results from the different density of the BN plate used in our work.

Next, we integrate Equation (8) over the 1ω BN nanotube proton spectrum to calculate the total number of activated nuclei. Here, the energy intervals for integration are between the threshold energy of the reaction (for negative Q values, zero elsewhere) and the 19 MeV maximum energy.

The results are summarized in Table 3. The first column shows the calculated alpha particle yield, which is 6 × 10⁶ per shot per J. The second column shows that the calculated ¹¹ C yield matches the measured one fairly closely. The difference could be due to the assumption of ±15° cone angle, which overestimates the proton yield for higher energies. Additionally, the catcher target featured some shallow ablation craters after the shot, which may have reduced the target activation due to some missing material.

Table 3: Reaction product yields per primary projectile in BN and expected yields for the BN nanotube 1ω spectrum.

The ion densities are calculated assuming the BN plate (density of 2.1 g/cm³) contains ∼95% BN and ∼5% oxygen contamination. The natural boron consists of 80%¹¹ B and 20%¹⁰ B. Of the natural oxygen, the ¹⁸ O isotope is about 0.2% abundant. N ₂ is given per shot per J of laser energy.

The third column compares the calculated and measured ¹³ N generation. In pure BN, ¹³ N can be generated by alpha particles [Reference Labaune, Baccou, Yahia, Neuville and Rafelski2], but since our target had significant oxygen contamination, there is also a very probable proton-induced reaction channel. Assuming that all alpha particles generated by the primary p-¹¹ B reaction (column 1) have energies between 1 and 5 MeV and are all stopped in the BN, the most optimistic calculation results in less than one ¹³ N nucleus being created per J. However, our measurement indicates that about 1300 nuclei/J are created. The calculated ¹³ N yield per alpha particle is ∼8 × 10⁻⁸. If we attribute all the measured ¹³ N nuclei as being created by alpha particles, this results in ∼2 × 10¹⁰ alpha particles per shot per J. Performing the same estimate for the ¹⁸ F yield (using a constant σ = 5 mb due to the lack of detailed cross-sectional data) results in a ¹⁸ F yield per alpha particle of 1.8 × 10⁻⁷, translating into ∼4 × 10⁸ alphas per shot per J. The two calculated alpha yields are inconsistent with each other by a factor of 50. The estimate from ¹³ N is also within a factor of two of the measured proton yield, which appears too high given the low fusion probability due to beam-target interaction.

Performing the ¹³ N calculation under the assumption of the proton-oxygen reaction results in a similar number as the measured one. The same comparison holds true for ¹⁸ F generation.

Therefore, we conclude that for our pitcher-catcher experiment, the majority of the measured radioactive isotopes are the result of protons interacting with ¹¹ B or oxygen contamination. However, some discrepancies still prevail between the calculated and measured data. In particular, the calculated ¹¹ C number is higher while the calculated ¹³ N is lower than measured, leaving room for potentially higher alpha numbers than calculated here.

3.5. Neutron Spectra

The data of the previous section show that the majority of the activation is from ¹¹ B (p, n)¹¹ C, which creates a neutron with each created ¹¹ C nucleus. For 14 J laser energy, this should create about 10⁶–10⁷ neutrons per laser shot. This neutron yield is detectable at ALEPH as shown in earlier works [Reference Curtis, Hollinger and Calvi14, Reference Curtis, Calvi and Tinsley19]. Figure 6(a) shows the neutron time-of-flight trace for the pitcher-catcher shots compared to shots using an Al pitcher only. The traces were averaged for 30 shots. The initial high-energy photon flash was very intense in all of the shots and created a temporary saturation of the traces followed by an exponential decay. Nonetheless, we have observed modulations of the traces during the decay of the scintillator for our pitcher-catcher shots with BN nanotube targets that were not present when the Al targets were used. To find out whether these modulations correspond to neutrons, and for a better comparison between the reference and pitcher-catcher shots, a multi-exponential function with constant offset was fitted to the decay curves and subtracted from the data to reveal a neutron signal. The fast rise time of the photon flash indicates the arrival time of the laser pulse on target, which was correspondingly used to calculate the neutron time-of-flight. Even with background subtraction, the data exhibit high-frequency noise and a poor signal-to-noise ratio due to the presence of a strong electromagnetic pulse. Using the noise amplitude of the Al data, for which we do not expect to measure any neutrons, we defined a baseline noise level of ±0.35 V (marked by the shaded area in Figure 6(a)). The amplitude of the pitcher-catcher signal at delay times between approximately 100 to 150 ns is significantly stronger than this noise level, suggesting it may be from neutrons.

Figure 6: Neutron time-of-flight data and spectra, from an average of 30 shots. (a) shows the background-corrected traces for the pitcher-catcher experiment vs. a pitcher-only aluminum target. The pitcher-catcher trace shows a signal at around 100 ns that is above the noise level. (b) shows the same data, converted to neutron kinetic energy. The first peak corresponds to ∼2–7 MeV energy, and a potential second peak is at ∼1.3 MeV energy. It is at present not clear whether this second peak is an artifact due to the noise; we have planned to investigate this in the future. The uncertainty in the detector distance leads to an error of the calculated energies, visualized by the shaded areas.

To generate a neutron spectrum, we disregard data that fall within the noise level by setting these values to zero. The time-of-flight data were converted to neutron kinetic energies and then sorted into a histogram with 0.1 MeV step size. We assume a constant detector response for the conversion from TOF into the spectrum. Since we had to change the bias voltage of the PMT to a level beyond our calibration, we cannot convert the PMT response to a neutron flux. In addition to that, the neutron signal occurred during the decay of the scintillator due to the strong gamma flash. The instrument response vs. neutron flux in this operating mode is not known. Therefore, the spectrum is given in “signal-per-0.1-MeV” units, which will only allow for qualitative but not for quantitative comparisons to our calculations.

The resulting spectrum corresponds to neutrons between 2 and 7 MeV, with an error of ±0.5 MeV due to uncertainties in the detector distance. The spectrum decays toward higher neutron energy. The irregular shape of the spectrum is partly due to the high-frequency noise mentioned above and partly due to the low neutron statistics (for ∼10⁶ neutrons emitted into 4π, about 10 neutrons per shot are hitting the detector). We also observe a single peak at about 1.3 MeV from the signal at ∼200 ns that is above the noise level. It is at present not clear whether this is an artifact due to the noise; we have planned to investigate this in the future.

To aid in the interpretation of the neutron data, we modeled an expected neutron spectrum using the 1ω BN nanotube proton spectrum as an input, together with the cross sections for (p, n) and (α, n) reactions from Table 1. The neutron spectra were generated using a custom Monte Carlo code to generate an exponentially decaying population of 10⁶ protons that resembled the measured spectrum, times a multiplicative factor to account for the actual number of protons. A second, Gaussian spectrum that is centered at 3 MeV with a FWHM of 1 MeV was used to simulate an assumed population of 10⁶ alpha particles, again times a multiplicative factor to correct for the actual number. For each population, the energy-dependent probability of creating a neutron was calculated via interpolation of the cross-sectional data tables. The neutron energy was determined by the nuclear reaction kinematics for binary collisions where the neutron is generated in the forward direction. The resulting neutron population was then converted to a histogram to generate the spectrum. The total number of neutrons was weighted by the primary particle numbers to calculate the relative neutron yields from protons and alpha particles. Figure 7(a) shows plots of the initial particle distributions (grey and black lines), plus the cross sections of the neutron-producing reactions. The alpha particle yield was assumed to be dominated by the number of 1 MeV protons, indicated by the blue circle.

Figure 7: Calculated vs. measured neutron spectra. (a) The cross-sectional data for neutron-producing reactions in BN show that multiple reaction channels for (p, n) and (α,n) exist with relatively high cross sections. The grey and black curves are plots of the p and α distributions used to generate the artificial neutron spectra shown in (b). Note that the alpha-generated neutron spectrum was multiplied by a factor of 1000 for visualization purposes; otherwise, its contribution to the total spectrum would not be visible. The comparison between the calculated and measured spectra shown in (c) shows that it is plausible that the measured neutrons originate from (p, n) reactions, showing its diagnostic potential. An (α, n) contribution to the measurement would fall into the same energy range. A potential (α, n) contribution cannot be resolved with the current measurement sensitivity.

Figure 7(b) shows the calculated neutron spectrum and its relative contributions from protons and alpha particles. Note that the alpha spectrum had to be multiplied by 1000 to become visible. This plot shows that the expected neutron energies from both kinds of projectiles overlap in their energies, and that for beam-target interactions as assumed here the neutron yield from protons far outweighs the neutron yields from alphas. Due to the interplay between the threshold energy to trigger the reaction and its cross sections, the spectrum is dominated by the ¹⁴ N (p, n)¹⁴ O reaction for energies below 2 MeV. Above that, the neutron spectrum is dominated by ¹¹ B (p, n)¹¹ C reactions. The proton-neutron spectrum decays toward higher energies due to the exponential proton spectrum.

Since we assume a Gaussian alpha particle spectrum centered at 3 MeV, the resulting alpha-neutron spectrum is shifted to about 4 MeV due to the reaction kinematics. The alpha-neutron energies are roughly centered in-between the proton-neutron energies. Overall, the neutron spectrum is dominated by (p, n) reactions in our experiments.

Figure 7(c) qualitatively compares the calculated neutron spectrum to the measured nTOF spectrum. The measured energies and slope are fairly well reproduced; however, the measured spectrum appears to fall into a narrower energy range. This may be due to an insufficient background correction of the measured data for reasons mentioned above, as well as due to the low particle statistics that result in near single events at the scintillator.