1 Introduction

The efficient compression of the available laser energy into an ever shorter pulse duration is an important tool in creating ultra-high-peak intensity laser pulses. Few-cycle, and even single-cycle, laser systems are routinely available at table-top (mJ and below) scale energy levels that have opened up a wide range of applications in strong-field physics, including time-resolved imaging and pump-probe studies. High-power, few-cycle laser pulses at the level of multiple Joules are considered an important next step in the efficient control over strong-field, laser–plasma processes to extend into the next level of practical applications related to particle acceleration and nuclear photonics^[ Reference Wheeler, Mourou and Tajima ^{1 ]}. While chirped pulse amplification (CPA)^[ Reference Strickland and Mourou ^{2 –} Reference Mourou ^{4 ]} has enabled the advancement of ever-growing energy levels into short pulse laser systems, the limitations in bandwidth for the amplifiers and stretcher–compressor technology has historically limited high-energy pulses from reaching their shortest possible duration, as defined by the carrier wavelength ( ${\tau}_\mathrm{p}\sim \lambda /c$ ). The post-compression techniques utilized in low-energy laser systems are typically based on photonic crystal fibers^[ Reference Markos, Travers, Abdolvand, Eggleton and Bang ^{5 ]}, hollow-core fiber waveguides^[ Reference Nagy, Simon and Veisz ^{6 ]} and multi-pass cells^[ Reference Hanna, Guichard, Daher, Bournet, Delen and Georges ^{7 ]}. Unfortunately, none of these approaches are well-suited even for sub-J laser pulses^[ Reference Khazanov ^{8 ]}.

In contrast, the thin film compressor (TFC), or compression after compressor approach (CAfCA), is demonstrated for the post-compression of just such large-scale CPA laser systems^[ Reference Chvykov, Radier, Chériaux, Kalinchenko, Yanovsky and Mourou ^{9 –} Reference Khazanov, Mironov and Mourou ^{11 ]}. The basic principle relies upon current concepts of post-compression where a nonlinear process such as self-phase modulation (SPM) introduces additional spectral bandwidth, and then the phase of the pulse must be controlled over the entire bandwidth to maintain the desired pulse duration. For the TFC, it is sufficient to use a transparent film of appropriate thickness interacting across the full aperture of the freely propagating flat-top, high-energy pulse within its transport from the final optical compressor to the final target. The intensity of these pulses – of the order of TW/cm² – is sufficient to drive nonlinear spectral broadening through SPM that arises from the time-dependence of the material index of refraction, $n(t) = {n}_0+{n}_2\kern0.1em I(t)$ , due to the influence of the laser intensity, $I(t)$ . Here, ${n}_0$ is the linear part of the refractive index and ${n}_2$ is the nonlinear refractive index. Due to the nature of the nonlinear laser–material interaction, the group delay dispersion (GDD) compensation required is primarily of second-order spectral phase correction. The dispersion correction factor ( $\alpha$ ) meant to optimize the GDD of the resultant pulse is most efficiently performed using optical elements such as chirped mirrors (CMs). One principle benefit of this configuration is the low energy losses during the SPM interaction, which allow for an efficiency over 90% and for several stages to compress the pulse to the desired duration. The low energy losses permit the option to employ multiple stages to decrease the pulse to the desired duration^[ Reference Ginzburg, Yakovlev, Zuev, Korobeynikova, Kochetkov, Kuzmin, Mironov, Shaykin, Shaikin and Khazanov ^{12 ]}.

The SPM process is the effect of the rapid change in the material index of refraction associated with the fast electric field oscillations of the intense laser pulses. The bandwidth modifications are easier to observe on laser systems with a shorter initial pulse. Thus, the compression technique has been studied at the TW-scale at several of these laser systems, including CETAL, ALLS, PEARL, ELI-NP and CoReLS^[ Reference Mironov, Wheeler, Gonin, Cojocaru, Ungureanu, Banici, Serbanescu, Dabu, Mourou and Khazanov ^{13 –} Reference Kim, Kim, Yang, Yoon, Sung, Lee and Nam ^{19 ]}, demonstrating up to five-fold pulse compression^[ Reference Ginzburg, Yakovlev, Zuev, Korobeynikova, Kochetkov, Kuzmin, Mironov, Shaykin, Shaikin, Khazanov and Mourou ^{20 ]}, and even six-fold^[ Reference Shaykin, Ginzburg, Yakovlev, Kochetkov, Kuzmin, Mironov, Shaikin, Stukachev, Lozhkarev, Prokhorov and Khazanov ^{21 ]}. The technique was applied in producing betatron radiation from laser wakefield acceleration (LWFA)^[ Reference Fourmaux, Lassonde, Mironov, Hallin, Légaré, Maclean, Khazanov, Mourou and Kieffer ^{22 ]} , and the method is now being implemented on PW-scale laser systems^[ Reference Ginzburg, Yakovlev, Kochetkov, Kuzmin, Mironov, Shaikin, Shaykin and Khazanov ^{23 ,} Reference Bleotu, Wheeler, Papadopoulos, Chabanis, Prudent, Frotin, Martin, Lebas, Freneaux, Beluze, Mathieu, Audebert, Ursescu, Fuchs and Mourou ^{24 ]}. A successful demonstration of the TFC on a laser system with an initial duration greater than 100  fs has great potential as an economical upgrade to existing picosecond-scale, high-energy laser systems, such as PETAL, OMEGA-EP and Vulcan.

To date, post-compression has been tested with long pulses at only tens of mJ^[ Reference Fan, Carpeggiani, Tao, Coccia, Safaei, Kaksis, Pugzlys, Légaré, Schmidt and Baltuška ^{25 ,} Reference Schulte, Sartorius, Weitenberg, Vernaleken and Russbueldt ^{26 ]} but preliminary numerical simulations for post-compressing PETAL laser parameters of 1  kJ, 0.5 ps and 200 mm diameter beam predict the ability to reach approximately 100 fs and suggest the peak power could be increased by nearly four times with a single-stage compressor^[ Reference Mironov, Wheeler, Gonin, Cojocaru, Ungureanu, Banici, Serbanescu, Dabu, Mourou and Khazanov ^{13 ]}.

In addition to existing laser installations, there is the possibility to apply the post-compression to novel designs. The need for an efficient high peak and average power laser driver is crucial for laser–plasma processes to be extended beyond discovery science and be put into practical application. A proposed solution for an industrial-scale, high-energy laser operating at more than or equal to 100 kHz employs a fiber chirped pulse amplification (FCPA) system. The small energy of a single fiber amplifier can be overcome by coherently combining several such amplifiers in parallel. This laser architecture concept is also known as the coherent amplification network (CAN). It has been introduced for driving particle acceleration^[ Reference Mourou, Brocklesby, Tajima and Limpert ^{27 ,} Reference Wheeler, Mourou and Tajima ^{28 ]} and systems with up to 61 fibers are under further development^[ Reference Soulard, Quinn and Mourou ^{29 ,} Reference Fsaifes, Daniault, Bellanger, Veinhard, Bourderionnet, Larat, Lallier, Durand, Brignon and Chanteloup ^{30 ]}. While efficiently producing pulses at a high repetition rate, the bandwidth limitation of a fiber-based amplifier places the minimum pulse duration near 300 fs and would require a post-compressor to reach the few-cycle pulse regime. Therefore, an FCPA laser system will likely benefit from highly efficient post-compression stages in order to reach a high compression factor. The development of an efficient and expandable CAN laser system based on fiber laser technology gives access to an economical and flexible tool capable of meeting the requirements of a wide range of applications, including the ability to drive the multiple stages of acceleration within a laser accelerator facility^[ Reference Nakajima, Wheeler, Mourou and Tajima ^{31 ]}.

The output bandwidth of the SPM process ( $\Delta {\omega}_\mathrm{spm}$ ) is proportional to the nonlinearity accumulated by the pulse in traversing the material^[ Reference Khazanov, Mironov and Mourou ^{11 ]}. This process is quantified using the B-integral parameter, ${B}_\mathrm{int} = \left(2\pi /\lambda \right)\cdot {I}_{\mathrm{o}}\cdot {n}_2\kern0.1em {\mathrm{\ell}}_{\mathrm{i}}$ , which takes into consideration the laser parameters of average peak intensity ${I}_\mathrm{o}$ , the wavelength $\lambda$ and the interaction distance ${\mathrm{\ell}}_\mathrm{i}$ _, with a material of nonlinearity ${n}_2$ . Due to the typical positive material dispersion ( ${k}_2>0$ , where ${k}_2$ is the group velocity dispersion), the expected broadening is reduced due to the decreasing intensity as the pulse stretches in time. Thus, the dispersion is dependent on the initial pulse duration with an increased sensitivity for a shorter pulse with a broader initial spectrum. These dispersion effects can be summarized in the term $D = {\mathrm{\ell}}_\mathrm{i}{k}_2/{\left({\tau}_\mathrm{p}\right)}^2$ , which considers again the interaction length, material dispersion and initial pulse duration. The model for the dependence on $B$ and $D$ of the spectral broadening relative to the original pulse spectrum is related to ${F}_{\omega}\equiv (\Delta {\omega}_\mathrm{spm}/\Delta \omega ) = 1+{g}_{\omega }{B}_\mathrm{int}(1-{h}_{\omega}\sqrt{D})$ . Here, ${g}_{\omega }$ and ${h}_{\omega }$ are fit parameters that were determined from simulations of SPM spectral responses under appropriate conditions to have values of ${g}_{\omega}\sim 0.91$ and ${h}_{\omega}\sim 1.5$ .

An advantage of beginning from long Fourier transform-limited (FL) pulses is the extremely weak influence of the linear dispersion of the medium. As the parameter $D$ is inversely proportional to the square of ${\tau}_\mathrm{p}$ , reducing $D$ improves the efficiency of the post-compression for a given ${B}_\mathrm{int}$ . An increase in the initial pulse duration also increases the maximum possible factor of compression in time, because the shortest duration for the pulse remains fixed by the optical cycle. Thus, employing multiple stages of compression can make possible the attaining of very high compression factors for these long pulses.

The dispersion management requires a high GDD, as the phase correction is proportional to the square of ${\tau}_\mathrm{p}$ . As exemplification, a 150 fs ( $\Delta \lambda \sim 11$ nm) pulse is only modified by GDD of the order of approximately $2.3\times {10}^4\ {\mathrm{fs}}^2$ and a pulse of 350 fs ( $\Delta \lambda \sim 5$ nm) requires GDD of approximately $1.2\times {10}^5\ {\mathrm{fs}}^2$ to induce a significant influence on the pulse duration.

This is highlighted within this experiment (see Figure 1, ELFIE laser, 350 fs) where the dispersion introduced by the diagnostic beam transport – including a set of CMs (–6000 fs²) – is not significant enough to show effects on the initial pulse, while the spectrally broadened pulse reaches bandwidths that are sensitive to the dispersion. For an existing beamline, any change in the pulse duration will need to consider the limitations of the subsequent optics in effectively transporting the modified pulse. Again, the use of multiple compression stages with each stage designed to accommodate the increasing bandwidth/decreasing FL pulse duration and the corresponding increase in pulse intensity will likely be required in order to reach the highest pulse compression factors.

Figure 1 The experimental setup for a demonstration of the post-compressor within the ELFIE interaction chamber. OAP is the off-axis parabolic mirror and TCC is its focus position.

As the peak power of the pulse exceeds the critical power ${P}_\mathrm{cr} = 3.79{\lambda}^2/\left(8\pi \kern0.1em {n}_0\kern0.1em {n}_2\right)$ ( ${P}_\mathrm{cr}\sim$ 4.5 MW for fused silica (FS)), the intense pulses with super-Gaussian modes are susceptible to multi-filamentation through the modulational instability initiated by noise in the beam profile^[ Reference Bespalov and Talanov ^{32 ]}. The process of spatial harmonic instability starts at a distance inside a nonlinear medium, where the nonlinear phase (or  B-integral) exceeds unity. Pulses where $P\gg {P}_\mathrm{cr}$ eventually break up into multiple filaments during propagation through a medium of sufficient length^[ Reference Rubenchik, Turitsyn and Fedoruk ^{33 ]}. The choice in thin film (TF) is to optimize the material interaction length that maximizes the spectral response while introducing minimal adverse effects on the spatial profile and pulse wavefront. The lower peak intensity of longer pulses requires more material to attain significant spectral broadening, which can be more economical to manufacture at the optical transmitted wavefront quality desired to minimize effects on the beam.

Therefore, the evolution of the small-scale self-focusing (SSSF) and multi-filamentation process that develops due to modulation instabilities in the beam must be considered in order to understand how it will be detected in measurements of the near-field profile. An important aspect is controlling the influence of the SPM process on the beam profile quality^[ Reference Voronin and Zheltikov ^{34 –} Reference Farinella, Wheeler, Hussein, Nees, Stanfield, Beier, Ma, Cojocaru, Ungureanu, Pittman, Demailly, Baynard, Fabbri, Masruri, Secareanu, Naziru, Dabu, Maksimchuk, Krushelnick, Ros, Mourou, Tajima and Dollar ^{36 ]} and the small-scale filamentation and beam break-up. Unmitigated development within the profile eventually leads to damage of the nonlinear material or subsequent optics and loss of pulse energy, and the aberrations diminish the achievable focus quality.

In this paper, measurements of spectral broadening and the influence of the SPM process for a sub-picosecond high-energy laser pulse interacting with glass and polymer materials are reported. Section 2 describes the experimental configuration implemented during the campaign at the ELFIE laser facility. Section 3 examines three aspects of the laser pulse following the nonlinear interaction: (1) the effect on the laser focus; (2) the measured spectral and the temporal responses are compared with the expectation from simulations; (3) the relative gain in the spatial modulation instabilities of post-compressed laser pulses. Section 4 summarizes the implications of the results in planning future  experiments.