2.1. Processing of the the CR39 detector

The CR39 is a kind of solid-state nuclear track detector. It is a transparent plastic with a chemical composition of $\text{C}_{12}\text{H}_{18}\text{O}_{7}$. When a charged particle passes through a CR39 detector, it deposits energy along the trail, mostly by ionization. A narrow damaged trail in the CR39, on the scale of nm, is formed. The amount of damage along the trail is mainly determined by the local electronic stopping power of the incident particle^{[Reference Fleischer, Price and Walker14]}. When the irradiated CR39 is exposed in an etchant, the surface is etched at a bulk velocity $v_{\text{B}}$, while the damaged trail is etched at a track velocity $v_{\text{T}}$. A visible track, on the scale of ${\rm\mu}\text{m}$, is formed after etching. The appearance parameters of the tracks are related to the species and energy of the incident particles. The CR39 detector has been widely used in many fields, such as ICF proton diagnostics, dosimetry for dose assessment and particle detection in space^{[Reference Séguin, Frenje, Li, Hicks, Kurebayashi, Rygg, Schwartz, Petrasso, Roberts, Soures, Meyerhofer, Sangster, Knauer, Sorce, Glebov, Stoeckl, Phillips, Leeper, Fletcher and Padalino11, Reference Caresana, Ferrarini, Fuerstner and Mayer15–Reference Zhou, Semones, Guetersloh, Zapp, Weyland and Benton17]}.

In this work, the etchant is $6~\text{mol}/\text{L}$ NaOH solution at a temperature of $80\,^{\circ }\text{C}$. The typical etching time is 6 h, and it can be set in a range of 2–9 h to make sure that the tracks are visible and there is no saturation. After etching, the CR39 detectors are rinsed with dilute acetic acid and highly purified water, and then dried. The appearance parameters of the particle track profiles are obtained from photos of the etched detector’s surfaces, by a digital microscope with objective magnifications of $20\times$ and $50\times$. The spatial resolution of the track diameter is approximately 1 and $0.4~{\rm\mu}\text{m}$ for the two magnifications, respectively.

2.2. Simulation of the track profile induced by a charged particle

Three track parameters are mostly used in the particle analysis: diameter, contrast and eccentricity. The diameter is always used to deduce the particle energy and species, while the contrast and eccentricity are used to reject the intrinsic tracks and neutron induced tracks^{[Reference Séguin, Frenje, Li, Hicks, Kurebayashi, Rygg, Schwartz, Petrasso, Roberts, Soures, Meyerhofer, Sangster, Knauer, Sorce, Glebov, Stoeckl, Phillips, Leeper, Fletcher and Padalino11]}. The track diameter has a nonlinear response to the particle energy, and it varies with the etching conditions. In the measurement with a specific etching condition (etchant, temperature and time), a well-defined empirical $V$-function ($V=v_{\text{T}}/v_{\text{B}}$) based etching kinematics model can describe the response well, and it has been studied in many works^{[Reference Caresana, Ferrarini, Fuerstner and Mayer15, Reference Zhou, Semones, Guetersloh, Zapp, Weyland and Benton17, Reference Nikezic and Yu18]}. In the application of ICF proton measurement, the etching time varies for different fusion yields and some other conditions. A semi-empirical model^{[Reference Hicks19]} of the $V$-function, independent of the etching time, has been proposed, as shown in Equation (1), where $\left(\frac{dE}{dx}\right)_{elec}$ is the local electronic stopping power along the trail, and $k$ and $n$ are the free parameters. In this section, a new etching kinematics simulation code based on a semi-empirical model is developed. The electronic stopping power is calculated by the TRIM code^{[Reference Ziegler, Ziegler and Biersack20]}. The track profiles of perpendicular incident particles and oblique incident particles are simulated.

(1)$$\begin{eqnarray}V=\frac{V_{\text{T}}}{V_{\text{B}}}=1+k\left(\frac{dE}{dx}\right)_{elec}^{n}.\end{eqnarray}$$

In the case of perpendicular incidence, the track profile can be calculated in two steps, as shown in Figure 1(a). The damaged trail is first etched to the point $A^{\prime }(y^{\prime },z^{\prime })$ in a time of $t^{\prime }$ at a velocity of $v_{\text{T}}(z)$. Then, the wall of the nano-hole is etched at a velocity of $v_{\text{B}}$ in the direction determined by the angle of ${\it\xi}$. In the time of ($t{-}t^{\prime }$), the track profile reaches the point $A(y_{A},z_{A})$. The two-step process can be described by Equations (2)–(4). The bulk etching depth can be calculated by Equation (5). With Equations (2)–(5), the track profile is obtained, shown as the solid line in Figure 1(a). The diameter, $D$, of the track on the surface is calculated using Equation (6). If the etchant has reached the particle range position R during the etching time, while the bulk etching depth is still less than the range (overetched case), as shown in Figure 1(b), the etchant first etches the trail to the range position at $v_{\text{T}}(z)$, and then etches around the wall at $v_{\text{B}}$ to form a spherical bottom. The solution of the track profile is similar to that in the non-overetched case. If the bulk etching depth exceeds the range of the particle (fully overetched case), the track profile is spherical, and the track image will have a low contrast and will usually be rejected.

(2)$$\begin{eqnarray}\displaystyle & z^{\prime }=\int _{0}^{t^{\prime }}v_{\text{T}}(z)dz, & \displaystyle\end{eqnarray}$$

(3)$$\begin{eqnarray}\displaystyle & \cos {\it\xi}=v_{\text{B}}/v_{\text{T}}, & \displaystyle\end{eqnarray}$$

(4)$$\begin{eqnarray}\displaystyle & z_{A}-z^{\prime }=v_{\text{B}}(t-t^{\prime })\cos {\it\xi}, & \displaystyle\end{eqnarray}$$

(5)$$\begin{eqnarray}\displaystyle & z_{A}=v_{\text{B}}t, & \displaystyle\end{eqnarray}$$

(6)$$\begin{eqnarray}\displaystyle & D=2y_{A}=2v_{\text{B}}(t-t^{\prime })\sin {\it\xi}. & \displaystyle\end{eqnarray}$$

Figure 1.

The track profiles in (a) the non-overetched case and (b) the overetched case for perpendicular incident particles.

In the case of oblique incidence, the track profile is solved by Equations (2)–(4) in $y^{\prime }$–$z^{\prime }$ coordinates and Equation (5) in $y$–$z$ coordinates, as shown in Figure 2. The shape of the track on the surface of the etched CR39 is no longer circular. If the bulk etching depth is not very large, for example surface $a$ or $b$, the surface track shape will be an ellipse. If the etching depth is very large, for example surface $c$, the shape will be an egg shape. This case often occurs in the tracks induced by neutron recoil protons.

Figure 2.

The track profiles for oblique incident particles.

Figure 3.

The measured and calculated energy responses of CR39 to proton, deuteron, triton and alpha.

Figure 4.

(a) The schematic setup of the D–D primary proton spectrometer at the SG-III prototype facility and (b) the measured proton spectra in the cool gas target (solid histogram) and the cryogenic $\text{D}_{2}$ target (dashed histogram) experiments with Gaussian fitting lines (blue lines).

2.3. Energy response calibration

The CR39 detector in this work was manufactured by Tastrak in UK. The energy responses of the track diameter to protons and alphas were measured at some energies, as the square and diamond points shown in Figure 3. For protons, the responses to 16 energies in the range of 0.7–3 MeV and three energies in the range of 4–10 MeV were measured at a $2\times 1.7~\text{MV}$ tandem accelerator and a $2\times 6~\text{MV}$ tandem accelerator, respectively, at Peking University. The uncertainties in the proton energy were less than 1%, and the incident proton beams were perpendicular to the CR39 surface. A timed aperture with a diameter of 1 cm was used to control the exposure time to avoid track saturation on the CR39. For alphas, the response to the 5.5 MeV alpha particles from a ²⁴¹Am source was measured. To limit the incident angle and the number of the alpha particles, the timed aperture was placed in between, 20 cm away from the source and 10 cm away from the CR39 plastic. The area of the CR39 plastic used for track readout was approximately 1 cm². The irradiated CR39 plastic was etched in $6~\text{mol}/\text{L}$ NaOH solution at a temperature of $80\,^{\circ }\text{C}$ for 6 h. By the mass loss of the unirradiated CR39 plastic before and after etching, the bulk etching velocity was measured as $\text{v}_{\text{B}}=1.793\pm 0.015~{\rm\mu}\text{m}/\text{h}$. By iterative fitting of the track diameters to the particle energies, the free parameters in Equation (1) were obtained as $k=3.3\times 10^{-4}$ and $n=2.4$. The calculated energy responses of the diameter to proton, deuteron, triton and alpha are also shown in Figure 3. With increase of the particle energy, the diameter decreases and the diameter decrease rate also decreases. Considering the track image spatial resolution and requirement of particle energy resolution, in routine proton measurements at the SG-III facility, readout proton tracks with diameters just in the range of 5–15 ${\rm\mu}\text{m}$ are used. Reference [Reference Sinenian, Rosenberg, Manuel, McDuffee, Casey, Zylstra, Rinderknecht, Gatu Johnson, Séguin, Frenje, Li and Petrasso21] reported that the piece-to-piece variation of the proton track diameter was approximately 19%. Considering the same etching conditions in this work as those in Ref. [Reference Sinenian, Rosenberg, Manuel, McDuffee, Casey, Zylstra, Rinderknecht, Gatu Johnson, Séguin, Frenje, Li and Petrasso21], in the following simulation work, a Gaussian distributed track diameter with the mean value of Figure 3 and a deviation of 19% was adopted. The detection efficiency was calculated as the probability that the track diameter would fall in the range of 5–$15~{\rm\mu}\text{m}$.

4.1. Design and response simulation of the SRF spectrometer

In ICF implosions, D–³He reaction protons are emitted by the primary reaction in the D–³He fuel implosion and the secondary reaction in the D–D fuel implosion. The proton yield and the energy downshift can be used to deduce the areal density^{[Reference Séguin, Li, Frenje, Hicks, Green, Kurebayashi, Petrasso, Soures, Meyerhofer, Glebov, Radha, Stoeckl, Roberts, Sorce, Sangster, Cable, Fletcher and Padalino4, Reference Hicks19]}. The high average proton energy (15 MeV) makes it possible to diagnose the areal density up to $100~\text{mg}/\text{cm}^{2}$. As a result, the energy dynamic range of the spectrometer is required to be wide, 8–18 MeV for example.

The SRF proton spectrometer uses a range of stepped filters to measure protons in different energy ranges^{[Reference Rosenberg, Zylstra, Frenje, Rinderknecht, Gatu Johnson, Waugh, Séguin, Sio, Sinenian, Li, Petrasso, Glebov, Hohenberger, Stoeckl, Sangster, Yeamans, LePape, Mackinnon, Bionta, Talison, Casey, Landen, Moran, Zacharias, Kilkenny and Nikroo12]}. An SRF proton spectrometer has been built at the SG-III facility for D–³He reaction proton measurement. The schematic diagram is shown in Figure 5(a). A set of 12 Al filters, with thicknesses from 500 to $1800~{\rm\mu}\text{m}$ with an interval of 100 ${\rm\mu}\text{m}$, was adopted in the SRF spectrometer. The CR39 detector was divided into 12 parts to record the transmitted protons. Proton tracks with diameters in the range of 5–15 ${\rm\mu}\text{m}$ were used. The low energy protons were ranged out by the filter to each cell, while the high energy protons were not counted by the CR39. Every cell in the spectrometer looked like an energy band-pass filter to the protons. In the response function simulation, the track diameters of the transmitted protons were calculated according to a Gaussian distribution with the mean values of Figure 3 and a deviation of 19%. The response function of each cell to proton energy is shown in Figure 5(b). With the help of the energy response matrix, a spectrum unfolding code based on a weighted averaging algorithm was also developed.

Figure 6.

The measured secondary proton spectra in the shot with a target diameter of $800~{\rm\mu}\text{m}$.

4.2. D–D implosion secondary proton measurement on the SG-III facility

The SRF proton spectrometer was first used in a $\text{D}_{2}$ exploding pusher target experiment on the SG-III facility in 2014. The spectrometer was installed on a general diagnostics instrument manipulator (DIM) and accessed the chamber in the middle plane. The distance between the target and the spectrometer was approximately 16 cm. The D–D secondary proton spectra in three shots were measured. The three targets had the same shell of $2~{\rm\mu}\text{m}$ thick $\text{SiO}_{2}$, while they had different diameters of 800, 620 and $450~{\rm\mu}\text{m}$. They were filled with 10 atm $\text{D}_{2}$ fuel. There were 32 laser beams directly driving the target, with a total energy of 30 kJ. In each shot, the hit positions on the target surface of the laser beams were shifted a little to decrease the root mean square (RMS) of the laser illumination. The measured proton spectrum for the $800~{\rm\mu}\text{m}$ diameter target is shown in Figure 6. The spectra in the other two shots were similar. The emitted protons were distributed mainly in the energy range of 12–18 MeV. There were no significant energy downshifts. This was consistent with expectations. Because the areal density of the exploding pusher target was very low, expected to be less than $1~\text{mg}/\text{cm}^{2}$, the energy downshift of secondary protons would be approximately 0.1 MeV, which was too small compared with the spectrometer energy resolution. However, the results show that the SRF spectrometer works well and is able to diagnose the areal density when it is higher than $10~\text{mg}/\text{cm}^{2}$. Moreover, from the spectra, the yields of the secondary protons were measured as $4.0\times 10^{6}$, $1.9\times 10^{6}$ and $9\times 10^{5}$, respectively. The neutron yields in the three shots were $3.1\times 10^{6}$, $1.9\times 10^{6}$ and $1.7\times 10^{6}$, respectively. A Monte Carlo code was developed to calculate the secondary proton emission, including the uniform hot-spot model and the ³He⁺ stopping power data calculated by the L–P model. According to the measured yield ratios of the secondary proton to primary neutron^{[Reference Cable and Hatchett23]}, the estimated areal densities of the three shots were 0.8, 0.7 and $0.4~\text{mg}/\text{cm}^{2}$, respectively.

5.1. Design and response simulation of the Si-WRF spectrometer

To overcome the disadvantage of low energy resolution in the SRF spectrometer, the WRF spectrometer was developed, which uses a wedged filter to replace the filter package. As illustrated in Figure 7(b), for incident mono-energetic protons, in the thicker end of the filter the protons will be ranged out, while in the thinner end the tracks of the transmitted protons will not be counted because of a track diameter smaller than $5~{\rm\mu}\text{m}$. The readout proton tracks are distributed in a narrow band on the surface of the CR39. By unfolding the proton track position spectra with the help of a well-defined energy response matrix, a high resolution incident proton spectrum can be obtained. There are already four types of WRF spectrometer, made from Al or $\text{ZrO}_{2}$ filters, developed at the OMEGA and NIF facilities^{[Reference Séguin, Sinenian, Rosenberg, Zylstra, Manuel, Sio, Waugh, Rinderknecht, Gatu Johnson, Frenje, Li, Petrasso, Sangster and Roberts13]}. A WRF spectrometer, made from a Si filter, has been set up at the SG-III facility for 6–18 MeV proton measurement. The Si filter has similar characteristics to the Al filter in the particle range, but the deformation is much smaller during storage. The structure of a single spectrometer is illustrated in Figure 7(b). A WRF spectrometer array consisting of five spectrometers was developed, as shown in Figure 7(a). The thickness range of the Si filter is 120–$2000~{\rm\mu}\text{m}$. Both the width and length of the filter are 4 mm. The WRF array will be installed on a DIM and will access the chamber in the middle plane. There will be three view angles in the poloidal direction and three in the azimuthal direction, which may be useful in implosion asymmetry diagnostics. The distance between the target and the array can be adjusted in the range of 16–50 cm. The maximum poloidal and azimuthal view angles are $\pm 20^{\circ }$.

Figure 7.

(a) The alignment of the Si-WRF spectrometer array at the SG-III facility (b) and a schematic illustration of a single WRF spectrometer^{[Reference Séguin, Frenje, Li, Hicks, Kurebayashi, Rygg, Schwartz, Petrasso, Roberts, Soures, Meyerhofer, Sangster, Knauer, Sorce, Glebov, Stoeckl, Phillips, Leeper, Fletcher and Padalino11]}.

A Monte Carlo simulation code based on the Geant4 package^{[Reference Agostinelli, Allisonas, Amako, Apostolakis, Araujo, Arce, Asai, Axen, Banerjee, Barrand, Behner, Bellagamba, Boudreau, Broglia, Brunengo, Burkhardt, Chauvie, Chuma, Chytracek, Cooperman, Cosmo, Degtyarenko, DellAcqua, Depaola, Dietrich, Enami, Feliciello, Ferguson, Fesefeldt, Folger, Foppiano, Forti, Garelli, Giani, Giannitrapani, Gibin, Cadenas, Gonzalez, Abril, Greeniaus, Greiner, Grichine, Grossheim, Guatelli, Gumplinger, Hamatsu, Hashimoto, Hasui, Heikkinen, Howard, Ivanchenko, Johnson, Jones, Kallenbach, Kanaya, Kawabata, Kawabata, Kawaguti, Kelner, Kent, Kimura, Kodama, Kokoulin, Kossov, Kurashige, Lamanna, Lampen, Lara, Lefebure, Lei, Liendl, Lockman, Longo, Magni, Maire, Medernach, Minamimoto, Freitas, Morita, Murakami, Nagamatu, Nartallo, Nieminen, Nishimura, Ohtsubo, Okamura, O’Neale, Oohata, Paech, Perl, Pfeiffer, Pia, Ranjard, Rybin, Sadilov, Di Salvo, Santin, Sasaki, Savvas, Sawada, Scherer, Sei, Sirotenko, Smith, Starkov, Stoecker, Sulkimo, Takahata, Tanaka, Tcherniaev, Tehrani, Tropeano, Truscott, Uno, Urban, Urban, Verderi, Walkden, Wander, Weber, Wellisch, Wenaus, Williams, Wright, Yamada, Yoshida and Zschiesche24]} was developed to study the spectrometer response and evaluate its capability. The simulated proton position spectra for 9 and 15 MeV mono-energetic protons are shown in Figure 8(a). The 1–4 MeV transmitted proton tracks are distributed in a 3 mm wide band. This indicates that the bin width of the recorded proton position spectra should be no more than 1 mm. The proton energy responses in the range of 4–19 MeV were also simulated with an energy interval of 0.1 MeV, as shown in Figure 8(b). This shows that the designed WRF spectrometer is able to work well in the range of 6–18 MeV. It can also be used as a well-defined energy response matrix in the following spectra unfolding code.

Figure 8.

(a) The energy response to 9 and 15 MeV mono-energetic protons and (b) the energy response matrix in the range of 4–19 MeV.

5.2. Capability evaluation

First, the capability of energy spectra reconstruction was evaluated. The test ‘experimental’ proton position spectra were simulated in the cases of different incident proton energy distributions. The spectra were unfolded by the MAXED code^{[Reference Reginatto, Goldhagen and Neumann25]}, which uses the maximum entropy algorithm. The energy response matrix was the simulated one in Figure 8(b). In the cases of mono-energetic proton incidence, the broadenings of the unfolded energy spectra were approximately 0.2 MeV, which represented the energy resolution of the WRF spectrometer. In the case of D–³He implosion primary proton incidence, two input Gaussian spectra were adopted with mean energies of 15 and 12 MeV and broadenings of 405 and 780 keV, respectively, as shown in Figure 9(a). The one with higher energy represented the proton emission spectrum at 5 keV ion temperature without energy downshift, while the other one represented the energy-downshifted proton spectrum in an areal density of 60–$70~\text{mg}/\text{cm}^{2}$. In the simulated ‘experiment’ with 10⁶ proton incidence, the unfolded spectra are also shown in Figure 9(a). They are consistent with the input Gaussian spectra. In the case of D–D implosion secondary proton incidence, a rectangular spectrum of 12–17 MeV was adopted as the simulation input. The unfolded spectrum and the input spectrum are consistent, as shown in Figure 9(b).

Figure 9.

(a) Comparisons of the unfolded spectra and the simulation input spectra in the cases of D–³He primary proton and (b) D–D secondary proton.

Figure 10.

The unfolded energy spectra under different incident proton counts in the cases of (a) D–³He primary protons and (b) D–D secondary protons.

Second, the effect of the proton counts was investigated. In the case of D–³He implosion, with an incident proton count of 10⁵–10⁸, which represents a yield range of 10⁸–10¹¹, the unfolded spectra are shown in Figure 10(a). This shows that when the D–³He primary proton yield exceeds 10⁸, the WRF spectrometer can work well. In the case of D–D implosion, with an incident secondary count of 10⁴–10⁷, which represents a primary yield range of 10¹⁰–10¹³, the unfolded spectra are shown in Figure 10(b). This shows that the necessary yield for WRF spectrometer measurement is approximately 10¹⁰.