2. Experiment and results

The experiment was performed using the Vulcan laser at the Rutherford Appleton Laboratory in the UK. Figure 1 shows a schematic of the experimental arrangement. Two picosecond synchronized laser beams, referred to as beams B7 and B8 (beams 1–6 are the long pulse beams of the Vulcan laser facility and are not used in this study), are used to drive THz generation and proton acceleration for heating, respectively. These beams are hereafter referred to as B7 and B8. B7 delivers pulses of $60\pm 7~ {\rm J}$ on the target with a duration equal to 1 ps, resulting in a calculated peak intensity of $(7.6\pm 0.9)\times 10^{19}~ {\rm W}~ {\rm cm}^{-2}$ when focused to a spot of $10~ \mu {\rm m}$ diameter (FWHM) at an incident angle of $8^\circ $ (with respect to the target normal). Note that this relatively small angle of incidence was chosen to minimize the production of transient surface currents of fast electrons^{[Reference McKenna, Carroll, Clarke, Evans, Ledingham, Lindau, Lundh, McCanny, Neely, Robinson, Robson, Simpson, Wahlstrom and Zepf14, Reference Gray, Yuan, Carroll, Brenner, Coury, Quinn, Tresca, Zielbauer, Aurand, Bagnoud, Fils, Kuhl, Lin, Li, Li, Roth, Neely and McKenna15]}, which can be a dominant driver of THz generation. B8 pulses have energy and duration equal to $200\pm 15~ {\rm J}$ and $12$ ps, respectively. They are focused to a $12~ \mu {\rm m}$ diameter (FWHM) spot, at an incident angle of $15^\circ $ (again with respect to the target normal), resulting in a calculated peak intensity of $(1.5\pm 0.1)\times 10^{19}~ {\rm W}~ {\rm cm}^{-2}$ . Both beams were controlled independently to enable either beam to be used separately or both used together with variable temporal separation of the pulses.

The THz generation target was a $200~ \mu {\rm m}$ thick amorphous carbon foil ( $3~ {\rm mm} \times 3~ {\rm mm}$ ); it is labeled E-target in Figure 1. The proton source target was a $20~ \mu {\rm m}$ thick gold foil ( $2~ {\rm mm}\times 2~ {\rm mm}$ ); it is labeled Heating-target. The inset of Figure 1 shows a top view of the experimental arrangement when both laser beams and targets were employed. The targets were orientated at a slight angle (not illustrated in the figure) such that the expanding proton beam from the Heating-target irradiated the E-target in the region of the B7 focus. The distance between the two laser foci was 1.7 mm. The temporal separation between the pulses was set such that B8 arrived on target $(85\pm 7)$  ps prior to B7. This enables sufficient time for the propagation of the multi-MeV proton beam from the Heating-target to the E-target, and an additional several tens of picoseconds for preplasma expansion.

Figure 2. (Color online) Typical THz waveforms (from an oscilloscope) as measured with a pyroelectric detector operating in the range 0.3–1 THz. Black: B7 only; red: B8 only; blue: both B7 and B8. The inset shows a reconstructed THz spectrum from a B7-only shot.

The main diagnostic is a broadband pyroelectric THz radiometer (Model SPI-A-62 from Spectrum Detector Inc.) coupled to a Tektronix oscilloscope. The detector has a flat response coefficient from 0.3 to 21 THz, with a calibrated responsivity of ${\sim }10^{4}~ {\rm V}~ {\rm W}^{-1}$ . Two 50 mm diameter polymethylpentene (TPX) lenses were used to collect and re-focus the THz radiation emitted in the backward direction at $20^\circ $ to the B7 laser axis. The focal lengths of these two optics are $f = 200~ {\rm mm}$ and $f = 100~ {\rm mm}$ . The electromagnetic (EM) radiation was transmitted out of the vacuum chamber through a 2 mm thick TPX window. The collection angle is limited to $8\times 10^{-4}~ {\rm sr}$ by the aperture size of the second lens. To prevent the detector being irradiated by high-energy particles, the sensor is oriented at an angle to the target and the measurement axis is turned by an aluminium mirror so that only the EM radiation is reflected onto the detector. The whole detector was housed in a 5 mm thick aluminum cylindrical cavity, which was further shielded by 50 mm thick lead bricks, leaving only a 5 mm diameter entrance hole. Several types of filter were used to ensure that the measured signal was in the THz frequency regime. A 1 mm thick piece of high-resistivity silicon (HR-Si) wafer was tightly fixed around the entrance hole to ensure that the arrangement was light-tight. Copper and stainless steel meshes of period 3 mm and 1 mm were stacked to remove EM noise below 0.3 THz. Different low-pass filters (QMMF mesh filter from QMC Instruments Ltd) were further employed to limit the upper cutoff frequency measured, to 10 THz, 5 THz, 1 THz, and 0.3 THz, enabling a crude THz spectrum to be determined.

Figure 3. (Color online) HELIOS simulation results. (a) and (c) Temperature and electron density profiles at the front surface of a carbon target at given simulation times, driven by the laser (B7) ASE only. (b) and (d) Corresponding temperature and density profiles for the same target driven by the laser (B7) ASE plus proton heating driven by B8. See the main text for details.

Example waveforms measured with the THz detector are shown in Figure 2, for three cases: (1) B7 only, (2) B8 only, and (3) both B7 and B8. The filters were chosen to transmit EM radiation in the range 0.3–1 THz. For the B7-only case, the measured signal peak voltage was 3.2 V and the duration (FWHM) was 4 ms. The signal decay time is set by the detector response, and is much longer than the actual THz pulse duration. The pulse energy detected is determined from the calibration to be $0.184~ \mu {\rm J}$ (equivalent to $230~ \mu {\rm J}~ {\rm sr}^{-1}$ if assuming isotropic emission and taking account of the diagnostic acceptance solid angle and the attenuations of the lens, window, and filters). The shot-to-shot reproducibility of the signal was checked over a series of laser shots on the same target type, and it showed a variation of ${<}10\%$ . The inset of Figure 2 shows a crude THz emission spectrum for the B7-only case. The central frequency for each point is the average of adjacent cutoff frequencies of the low-pass edge filters, and the horizontal error bars are obtained from their differentiation. The amplitude of the signal is plotted at the detector voltage per unit frequency (in THz). The vertical error bars reflect the degree of shot-to-shot fluctuation and account for systematic errors. The result indicates that the measured THz emission is mainly at relatively low (up to 1 THz) frequencies.

To determine if the B8 interaction with the proton source target contributes to the measured THz signal, measurements were made with B8 only. The energy of the THz pulse in this case was only $1.4~ \mu {\rm J}~ {\rm sr}^{-1}$ , which is more than two orders of magnitude smaller than the B7 interaction, indicating that the THz emission is dominated by the B7 interaction. In shots for which both B7 and B8 are used, i.e., corresponding to proton pre-heating of the main target (E-target), the measured THz energy decreases, compared to the equivalent case without proton heating, by more than a factor of 2, to $106~ \mu {\rm J}~ {\rm sr}^{-1}$ .

We now consider the changes to the main target induced by the proton beam. The interaction of B8 with the thin gold target accelerates protons via the target normal sheath acceleration (TNSA) mechanism^{[Reference Wilks, Langdon, Cowan, Roth, Singh, Hatchett, Key, Pennington, MacKinnon and Snavely16]}. About $5\%$ of the laser pulse energy is converted to produce a proton beam with an exponential spectral distribution, with temperature ${\sim }2~ {\rm MeV}$ and cutoff energy equal to 14 MeV. The spectrum is measured, using a stack of dosimetry film, with the E-target in position so that the missing fraction, i.e., the protons absorbed by the E-target, can be determined.

Proton stopping within the target is governed by the Bragg peak energy deposition profile. The resulting target heating and hydrodynamic expansion are modelled using the 1D HELIOS-CR radiation-hydrodynamic code^{[Reference MacFarlane, Golovkin and Woodruff17]}and the PROPACEOS equation of state (EoS). The temporal separation of the arrival of B7 and B8 at their respective targets is 85 ps. Protons with energy of 8 MeV, for example, will transverse the 1.7 mm distance from the source to the focal position of B7 in 43 ps, with the larger number of 2 MeV protons arriving after 85 ps. The majority of the protons thus arrive and start heating the E-target in the temporal window from around 40 ps prior to the arrival of the peak of B7. This sets the range of expansion times to be modelled in the HELIOS calculations. Note that, as with similar studies involving target heating driven by TNSA protons from a secondary laser-foil interaction (e.g., [Reference Mancic, Robiche, Antici, Audebert, Blancard, Combis, Dorchies, Faussurier, Fourmaux, Harmand, Kodama, Lancia, Mazevet, Nakatsutsumi, Peyrusse, Recoules, Renaudin, Shepherd and Fuchs18]), we assume that, compared to proton heating, x-ray and fast-electron emission from the secondary foil contributes relatively little to the heating of the front surface of the primary target, due to the Bragg peak energy deposition profile and relatively high directionality of the proton beam. Another factor which must be considered is the amplified spontaneous emission (ASE) of B7 which arrives at the target prior to the protons. Contrast measurements made on the Vulcan laser indicate that the level of the ASE intensity is of the order of $10^{10}~ {\rm W}~ {\rm cm}^{-2}$ at $0.1\mbox{--}1~ {\rm ns}$ , and $10^{11}~ {\rm W}~ {\rm cm}^{-2}$ at $50\mbox{--}100~ {\rm ps}$ prior to the peak of the laser pulse.

3. Simulations and discussion

HELIOS simulations were performed for two cases: (1) B7 ASE only (i.e., no proton heating) and (2) B7 ASE plus the proton beam. The simulation starts at $t=0$ with the arrival of the ASE on target and runs until $t=1.3~ {\rm ns}$ . The ASE intensity is $10^{10}~ {\rm W}~ {\rm cm}^{-2}$ from $t=0\mbox{--}1~ {\rm ns}$ , and $10^{11}~ {\rm W}~ {\rm cm}^{-2}$ from $t=1\mbox{--}1.3~ {\rm ns}$ . For case (2), 8 MeV protons arrive at the target at $t=1.2~ {\rm ns}$ , while lower-energy protons arrive later: 1 MeV protons arrive at $t=1.28~ {\rm ns}$ . The peak of B7 also arrives at $t=1.28~ {\rm ns}$ .

The resulting target heating and front surface plasma expansion profiles at given simulation times are shown in Figure 3. The ASE-only simulations (Figures 3(a) and 3(c)) show that the primary effect of the ASE pedestal is to heat the underdense region of the target and drive a low-temperature shock wave into the target, resulting in compression of the first micron depth of the target by ${\sim }25\%$ . The target heating and expansion driven by the ASE is relatively small. For the case in which the proton beam is added, we find that the first few tens of microns depth from the front surface of the target is heated to temperatures of ${\sim }10~ {\rm eV}$ , as shown in Figure 3(b), with an exponential decrease in temperature to about 0.3 eV at a depth of $100~ \mu {\rm m}$ . Similar laser-driven proton heating profiles have been reported in other work^{[Reference Mancic, Robiche, Antici, Audebert, Blancard, Combis, Dorchies, Faussurier, Fourmaux, Harmand, Kodama, Lancia, Mazevet, Nakatsutsumi, Peyrusse, Recoules, Renaudin, Shepherd and Fuchs18]}. Importantly, we find that the target front side expands faster into vacuum in response to this heating, resulting in slightly larger plasma scale length, compared to the case of ASE-only heating.

There have been a few mechanisms proposed for THz emission from relativistic laser interaction with solid targets. One of them is associated with the space-charge field or laser wakefield excitation at the vacuum–plasma interface driven by the laser ponderomotive force^{[Reference Hamster, Sullivan, Gordon and Falcone1, Reference Sheng, Wu, Li and Zhang19–Reference Gorbunov and Frolov21]}. This mechanism requires a large volume of underdense plasma at densities below $10^{19}~ {\rm cm}^{-3}$ , with scale length longer than the length of the driving laser pulse; otherwise, the generation efficiency is low. Our fluid simulations of preplasma formation reveal that the additional proton heating, which strongly affects THz emission, mainly changes the density scale length in a localized region at densities of the order of $n_c$ ( ${\sim }10^{21}~ {\rm cm}^{-3}$ ). It therefore appears that the contribution of THz emission due to this mechanism is less important. As discussed above, other THz generation mechanisms are associated with energetic electron production, such as the surface transient current at the front^{[Reference Li, Li, Zhou, Wang, Du, Ding, Lin, Liu, Sheng, Peng, Chen, Ma, Lu, Wang, Wei and Zhang3]}or rear^{[Reference Gopal, Herzer, Schmidt, Singh, Reinhard, Ziegler, Brommel, Karmakar, Gibbon, Dillner, May, Meyer and Paulus22]}, antenna emission^{[Reference Sagisaka, Daido, Nashima, Orimo, Ogura, Mori, Yogo, Ma, Daito, Pirozhkov, Bulanov, Esirkepov, Shimizu and Hosoda2]}, and transient radiation^{[Reference Zheng, Tanaka, Miyakoshi, Kitagawa, Kodama, Kurahashi and Yamanaka23–Reference Ding, Sheng and Koh25]}, which occur when the preplasma has moderate-to-short density scale lengths. Generally, all of these mechanisms depend upon the preplasma conditions in two ways, by changing (1) the absorption of laser energy to fast electrons, and (2) the injection properties of the fast-electron distribution (see reference [Reference McKenna, Carroll, Lundh, Nurnberg, Markey, Bandyopadhyay, Batani, Evans, Jafer, Kar, Neely, Pepler, Quinn, Redaelli, Roth, Wahlstrom, Yuan and Zepf26] for an example study of the sensitivity to preplasma scale length). A relatively large preplasma usually produces more hot electrons with higher temperature, which often leads to higher transient currents near the target surface when the laser is incident at relatively large angles with respect to the target normal. Two features distinguish the present work from previous studies: the laser (B7) is incident at a relatively small angle ( $8^\circ $ ), and our approach using proton heating over a large area of the target surface drives quasi-1D preplasma expansion. The results which show that THz emission is reduced with increasing preplasma expansion, which are in broad agreement with a previous study under different conditions^{[Reference Li, Zhou, Ding, Du, Liu, Li, Wang, Sheng, Ma, Chen, Lu, Dong, Wang, Lou, Shi, Wei and Zhang10]}, are explained partially by the fact that transient currents formed deeper into the expanded preplasma cannot emit THz waves out of it because of their low frequency. These effects will be investigated in more detail in further work.