Introduction

The method of chirped pulse amplification has massively increased the peak power of laser pulses. Modern lasers can reach intensities exceeding 1021 W cm−2, high enough that the free electrons undergo relativistic oscillations in the wave. This high intensity is achieved by compressing the pulses to their transform limited duration with a set of reflective gratings, and subsequent focussing1. However, the damage threshold of these components limits the peak achievable intensity.

There are predictions that even greater intensities, of the order 1024 W cm−2, will introduce quantum electro-dynamics processes, such as vacuum phase shifts2, 3 and electron–positron pair production4. The resultant gamma ray bursts will have numerous applications in nuclear physics5 and industrial sensing. However, it is impractical and expensive to scale up current solid-state optics, and so laser compressors with greater damage thresholds may be required to study these processes. High energy picosecond pulses, ideally in the ultra-violet, also have implications in inertial confinement fusion. The fast particle beams generated by these short pulses would provide auxiliary heating to the fusion fuel, either through collisional stopping6, 7 or two beam instabilities8,9,10. Since damage thresholds of solid state devices decrease in the ultra-violet range, ionised compression or gain media will be required.

It was discovered by Malkin et al.11 that a plasma can act as a pulse compressor, with an electron plasma wave mediating energy from one pulse to another. This proceeds so long as the short seed pulse has frequency ω1 = ω0 − ωp, where ω0 is the frequency of the counter-propagating long-pump pulse and ωp is the electron plasma frequency12. Plasma permits a much higher output intensity than solid state optics13, possibly by a factor of 105. The plasma should be uniform14 and approximately one hundredth of the pump pulse critical density15, 16.

In the original proposal for Raman amplifiers, a pre-focussed geometry was envisaged11. However, in the derivation given there, the beams were assumed to be collimated. In this work, we generalise those coupled envelope equations to include the case of a converging or diverging Gaussian beam and recover the results of Malkin et al.11 as a special case. We show that the new diverging geometry minimises the required seed pulse energy. It also eliminates the wastage of energy in to the usual trailing secondary peaks of the amplified pulse. These facts indicate that a greater output power will be achievable using the diverging geometry, rather than a collimated geometry.

Results

Proposed geometry

The collimated amplifier evolves as follows17: energy is transferred from the pump to the seed pulse, and in the non-linear stage of the instability, the pump is fully depleted. The seed pulse amplitude a1 grows linearly with time. The pump and seed amplitudes are defined as a0,1 = eE0,1/(0,1c), where m is the electron mass, E0 is the peak electric field of the pump and E1 is that of the seed. As it amplifies, the full width at half maximum duration of the seed pulse T1 decreases inversely proportional to time, such that

$$a_1T_1\sqrt {\omega _0\omega _{\mathrm {p}}} \simeq 5.$$
(1)

In fact, Eq. (1) also gives the condition for the Raman scatter to deplete the pump pulse15. Since the energy transfer is proportional to the pump depletion, the amplification is only highly efficient when Eq. (1) is met.

However, this requirement on a1 poses a problem, since it is difficult to generate intense seed pulses at the shifted wavelength. One method is to utilise non-linear optics effects in a neutral gas cell. It may also be possible to use optical parametric chirped pulse amplification to generate intense tune-able seed pulses, at the cost of increased complexity and timing issues. Even in the most successful experiment yet18, 19, the 880 nm wavelength seed pulse only had \(a_1T_1\sqrt {\omega _0\omega _{\mathrm {p}}} \simeq 0.3\). The measured plasma amplifier energy efficiency was 6.4%. The low power seed meant this was far below the theoretical maximum of 1−ωp/ω0 90%.

Since Eq. (1) is independent of the transverse dimension, an obvious tactic to reach the non-linear stage is to start the amplification with the seed pulse at its focus, where its intensity is maximum. This is in contrast to the geometry proposed in ref. 11. For example, a 1 μm wavelength, 50 fs seed pulse with energy 1 mJ in a plasma of electron density 1019 cm−3 could easily achieve \(a_1T_1\sqrt {\omega _0\omega _{\mathrm {p}}}\) = 5 with a focal beam waist of 6 μm. In addition, this high initial seed intensity will also permit use of the seed ionisation scheme20,21,22, where the plasma is not ionised until the short seed pulse arrives. This has the significant advantages of keeping the electron temperature low and avoiding instabilities of the pump pulse, since it traverses a neutral gas until it meets the seed.

With such a narrow beam waist, the amplifier length may be longer than the Rayleigh length and so it is not valid to assume a collimated beam. In fact, we will now assume that the amplification occurs outside of the Rayleigh range. The new proposed geometry is shown in Fig. 1. The seed approaches from the left side and is amplified as it diverges through the plasma. Note that this closely replicates the geometry of typical high-power laser systems, which start with a low power, narrow seed and increase the diameter as it amplifies. The pump and seed overlap may be maximised by matching the focal geometry of the pump to that of the seed, with the pump counter-propagating.

Fig. 1
figure 1

Schematic of the proposed diverging Raman amplifier geometry. The seed pulse (red) starts in the amplifier at its focus, where it is met by the counter-propagating long-pump pulse (black). It amplifies through the plasma (purple) as it diverges outside of the Rayleigh range. A curved plasma mirror (grey) focusses the amplified pulse to a controllable focal position. Alternatively, the pump may arrive from a different angle, past the side of the plasma mirror

The disadvantage of this scheme is that the amplified pulse will require subsequent focussing. However, it may exceed the damage threshold of conventional optics. It should be possible to focus it with a spherical plasma mirror23, 24, as shown in Fig. 1. This will have the added advantage of improving the pulse contrast. The mirror may be placed at a position where the low intensity pump will propagate through the back of it, but the amplified pulse will ionise and reflect from it. Alternatively, the pump may arrive from a different angle, past the side of the plasma mirror. This mirror will allow control over the final focal position.

The transverse beam profile outside of the Rayleigh range may be a concern, however the low energy of the seed pulse will allow the use of adaptive optics to smooth any transverse phase imperfections. As shown in ref.25, the pump pulse must be energetic, but need not have the same coherence, since any imperfections will be transferred to the plasma wave and not the amplified pulse. A longer amplifier for the compression of nanosecond pulses will also use a much lower plasma density26, lowering the effect of competing instabilities.

Generalisation of the envelope equations

To investigate how the beam geometry affects the amplification, the coupled envelope equations from ref.11 will now be generalised to include non-collimated beams. Including the transverse diffraction term from the paraxial Helmholtz equation, the amplified pulse amplitude a1(x, t) evolves as27

$$\partial _ta_1 - c\partial _xa_1 - \frac{{ic^2}}{{2\omega _1}}\left( {\partial _y^2 + \partial _z^2} \right)a_1 = - \frac{{\omega _{\mathrm {p}}^2}}{{4\omega _1}}a_0n_2^ \ast .$$
(2)

In this equation, spatial and temporal partial derivatives are written as ∂ x and ∂ t . The pulse propagates along the x axis and the origin is at the focus. The dimensionless plasma wave amplitude n2 is normalised to the average electron density. The dispersion of the waves is neglected. The amplified pulse vector potential is given by the real part of \(\widehat {\bf{y}}\)(mc/e)a1 exp(ik1x + 1t). The envelope model assumes that the pulses are much longer than one wavelength and damping processes are negligible.

To maximise the pulse overlap, the length of the amplifier should be cT0/2, where T0 is the pump pulse duration. For a 1 ns long-pump pulse, as found at many high-power laser facilities, the amplifier will be 15 cm long. For the parameters described earlier, the beam waist was wf = 6 μm, giving the Rayleigh length \(L_{\mathrm {R}} = \omega _1w_{\mathrm {f}}^2{\mathrm{/}}(2c)\) = 113 μm. This means most of the amplification length will have \(x \gg L_{\mathrm {R}}\).

Assuming the seed pulse is a perfect Gaussian beam along the x axis, the transverse Laplacian can be evaluated to give the amplitude on the x axis as

$$\partial _ta_1 - c\partial _xa_1 + \frac{{icL_{\mathrm {R}}}}{{x^2}}a_1 - \frac{c}{x}a_1 = - \frac{{\omega _{\mathrm {p}}^2}}{{4\omega _1}}a_0n_2^ \ast .$$
(3)

The third and fourth terms have been Taylor expanded to leading order, assuming that \(x \gg L_{\mathrm {R}}\). This assumption also means the third term in Eq. (3) is negligible with respect to the fourth. Furthermore, the maximum of the short pulse will be close to the position x = −c(t − tf), where tf is the time of best focus. This is the approximate coordinate for the whole pulse, assuming that the pulse duration is much less than t − tf. The seed pulse propagates towards negative x and the pump pulse propagates towards positive x. In typical situations, the plasma is very under-dense, so that \(\omega _{\mathrm {p}} \ll \omega _0\). Along with the other equations from ref. 11, this leads to the system

$$\left( {\partial _{{t}} + 2c\partial _x} \right)a_0 = \frac{{\omega _{\mathrm {p}}^2}}{{4\omega _0}}a_1n_2,$$
(4)
$$\partial _ta_1 + \frac{{a_1}}{{t - t_{\mathrm {f}}}} = - \frac{{\omega _{\mathrm {p}}^2}}{{4\omega _1}}a_0n_2^ \ast ,$$
(5)
$$\left( {\partial _t + c\partial _x} \right)n_2 = - \frac{{\omega _0^2}}{{\omega _{\mathrm {p}}}}a_0a_1^ \ast .$$
(6)

The time t is measured from the start of the non-linear stage. The equations have been written in a spatial coordinate system moving along with the seed pulse, with the front of the seed pulse remaining approximately at x = 0. The new geometric term has been neglected for the plasma wave, since its phase velocity is much less than c. In addition, the unperturbed pump amplitude will barely change within the extent of the short seed pulse, so its geometrical term can be neglected. However, since the pump is focussing and its power may change, the incoming pump amplitude a0(t, 0) is treated as time dependent.

Following the method of ref.11, when the pump is heavily depleted, the interaction will be short and so the time derivatives may be neglected with respect to the spatial derivatives in Eqs. (4) and (6). This will give the evolution in the late non-linear stage, where the seed duration is much less than its timescale of evolution. The equations become

$$2c\partial _xa_0 = \frac{{\omega _{\mathrm {p}}^2}}{{4\omega _0}}a_1n_2,$$
(7)
$$\partial _ta_1 + \frac{{a_1}}{{t - t_{\mathrm {f}}}} = - \frac{{\omega _{\mathrm {p}}^2}}{{4\omega _1}}a_0n_2^ \ast ,$$
(8)
$$c\partial _xn_2 = - \frac{{\omega _0^2}}{{\omega _{\mathrm {p}}}}a_0a_1^ \ast .$$
(9)

Again following refs. 11, 20, we now introduce the trial function u(x, t) and the trial solutions a0(x, t) = α0(t) cos(u/2), a1(x, t) = α1c x u and n2(x, t) = α2(t)sin(u/2). The variable α0 is the incoming pump amplitude at the start of the seed pulse.

Substituting these trial solutions in to Eqs. (7) and (9) leads to α1 = \(\sqrt {2{\mathrm{/}}\left( {\omega _0\omega _{\mathrm {p}}} \right)}\) and α2 = −α0(2ω0/ωp)3/2. Equation (8) then gives

$$\left( {\partial _t + \frac{1}{{t - t_{\mathrm {f}}}}} \right)\partial _xu = \frac{{\omega _0\omega _{\mathrm {p}}}}{{4c}}\alpha _0^2{\kern 1pt} {\mathrm{sin}}(u).$$
(10)

Self-similar amplification

We first find the solution for constant pump pulse amplitude, when α0 is constant. In this case there is a self-similar solution11. This means that the amplitudes of the three waves, for all values of x and t, depend only on the dimensionless coordinate β = \(\omega _0\omega _{\mathrm {p}}\alpha _0^2xt{\mathrm{/}}(4c)\). This can be shown by changing variables in Eq. (10) and writing u(x, t) = f(β), leading to

$$\beta \frac{{{\mathrm {d}}^2f}}{{{\mathrm {d}}\beta ^2}} + \left( {\frac{{2t - t_{\mathrm {f}}}}{{t - t_{\mathrm {f}}}}} \right)\frac{{{\mathrm {d}}f}}{{{\mathrm {d}}\beta }} = {\mathrm{sin}}(f).$$
(11)

The variable t has not been eliminated by the change of variables and so the evolution of the pulse is not, in general, self similar. However, in the limit \(\left| {t_{\mathrm {f}}} \right| \gg t\), Eq. (11) depends only on β and the equation reduces to the self-similar behaviour found in ref. 11. In this limit, the focus is very far away compared to the scale of the interaction.

There is also self-similar behaviour in the limit \(\left| {t_{\mathrm {f}}} \right| \ll t\), which applies when the non-linear stage starts at or very near the focus of the amplified pulse. Since t is positive, this means t − tf > 0 and so this limit will only apply to the case of a diverging beam and not a converging beam. This is the limit illustrated in Fig. 1. In this new geometry, the self similar equation becomes

$$\beta \frac{{{\mathrm {d}}^2f}}{{{\mathrm {d}}\beta ^2}} + 2\frac{{{\mathrm {d}}f}}{{{\mathrm {d}}\beta }} = {\mathrm{sin}}(f).$$
(12)

This equation is identical to that of the collimated case with \(\left| {t_{\mathrm {f}}} \right| \gg t\), found by Malkin et al.11, except the coefficient of the first order term is increased from 1 to 2.

The numerical solution to Eq. (12) is shown in Fig. 2. It has a similar form to the standard collimated solution. The pulse is composed of many peaks that are slightly lower intensity than in the collimated case, although a greater fraction of the energy now resides in the main front-most peak. The Eq. (1) still holds. The usual scaling laws still hold, so that the pulse amplitude increases a1t and the seed duration shortens 1/t. Considering the divergence of the pulse, the seed power increases t4 and the seed energy increases t3.

Fig. 2
figure 2

Numerical integration of the self-similar equations for the limit of a collimated beam (solid line) or a diverging beam (Eq. (12), dashed line). The boundary condition was f(0) = 0 and f′(0) = 0.001, corresponding to a small initial seed. a f as a function of the dimensionless self-similar coordinate β. It tends towards π for both cases. b The development in the f, f′ plane. c The shape of the amplified pulse temporal power envelope, as found from these solutions. Propagation is towards the left

Steady-state amplification

Returning to Eq. (10), there is a solution when ∂ t u = 0. The steady-state solution satisfies

$$\partial _xu = \frac{{\omega _0\omega _{\mathrm {p}}\left( {t - t_{\mathrm {f}}} \right)}}{{4c}}\alpha _0^2{\kern 1pt} {\mathrm{sin}}(u).$$
(13)

Therefore, if \(\alpha _0 \propto 1{\mathrm{/}}\sqrt {t - t_{\mathrm {f}}}\) then the amplified pulse will have a temporal envelope that is constant as it amplifies. The pulse intensity and duration will be constant, however the power and energy will increase t2 as the pulse diverges.

For the converging pump pulse in three dimensions, \(\alpha _0 \propto 1{\mathrm{/}}\sqrt {t - t_{\mathrm {f}}}\) requires its power to increase linearly with time t − tf. Pulse shaping such as this is routinely achieved on many large-scale systems such as the national ignition facility28. Introducing the proportionality constant a = (t − tf) \(\alpha _0^2\sqrt {\omega _0\omega _{\mathrm {p}}{\mathrm{/8}}}\), the solution to Eq. (13) is

$${\mathrm{tan}}\left( {\frac{u}{2}} \right) = {\mathrm{exp}}\left( {a\sqrt {\frac{{\omega _0\omega _{\mathrm {p}}}}{{2c^2}}} \left( {x - x_0} \right)} \right)$$
(14)
$$a_1(x) = a{\kern 1pt} {\mathrm{sech}}\left( {a\sqrt {\frac{{\omega _0\omega _{\mathrm {p}}}}{{2c^2}}} \left( {x - x_0} \right)} \right).$$
(15)

The constant a is therefore the peak amplitude of the scattered pulse. The integration constant x0 is the position of the pulse maximum.

After an initial start-up stage, the pulse converges towards a single, constant intensity spike that monotonically depletes the pump pulse. There are no trailing secondary peaks. This has great significance, since in the collimated case as much as 40% of the pulse energy is wasted in to the secondary peaks, shown by the solid line in Fig. 2c. The increased prominence of the first spike of the amplified pulse is comparable to that predicted by Toroker et al.29 when a chirped seed pulse is used. For the steady-state amplifier, the amplitude duration product is modified to

$$aT_1\sqrt {\omega _0\omega _{\mathrm {p}}} \simeq 2.5.$$
(16)

Equations (1) and (16) show that, for the same energy, the diverging pulse will have four times the peak power of a pulse from a collimated amplifier.

Taken together, these facts mean that a much greater peak intensity could be reached with the diverging beam scheme rather than the collimated scheme, possibly by a factor of four or more. A shorter, single spike is the desired pulse profile for many uses in high energy density science. To reach a similar power output with collimated beams, a much greater beam diameter and a correspondingly more powerful seed pulse would be required.

A further advantage of this scheme over the collimated case is that the pulse will never reach relativistic intensity. In the collimated case, the length of the amplifier is limited by de-tuning due to the relativistic electron non-linearity30. This can happen even before the pulse degrades in to transverse filaments31, 32. In the new geometry, this problem is eradicated and the length is only limited by competing plasma instabilities.

Particle in cell simulation

The diverging seed ionisation scheme may be investigated with the use of fully kinetic particle simulations that initialise perfect Gaussian laser pulses. Although, full three-dimensional (3D) simulations are currently infeasible, the steady-state behaviour is also observed in two-dimensional (2D) Cartesian simulations. This is provided that, as before, α0 1/\(\sqrt {t - t_{\mathrm {f}}}\) outside its Rayleigh range. The derivation proceeds as before, except a becomes 2a.

The particle-in-cell code Osiris33, 34 was used to model the amplification of a diverging seed pulse. To reduce computational expense, the simulation used a spatial domain that enclosed only the seed pulse and moved with it. The domain size was 125λ0 by 1000λ0 transversely, where λ0 is the pump wavelength.

To model the seed ionisation scheme, a neutral hydrogen gas was initialised across the entire simulated volume. A field ionisation model was used to initialise the free electrons at the appropriate time within the simulation. The electrons were initialised with temperature 50 eV and uniform density 1019 cm−3. The laser pulses were initialised as ideal Gaussian beams. The long-pump pulse had a constant wavelength 1.054 μm and on-axis amplitude that decreased as α0 1/\(\sqrt {t - t_{\mathrm {f}}}\) outside of the Rayleigh range, such that a = \(\left( {t - t_{\mathrm {f}}} \right)\alpha _0^2\sqrt {\omega _0\omega _{\mathrm {p}}{\mathrm{/}}8}\) = 0.08. The focal beam waist was 6 μm.

The seed pulse was initialised at its focus, exactly counter-propagating with the pump pulse. The focal position and beam waist were the same as for the pump. The central wavelength was 1.18 μm, its peak amplitude was a1 = 0.1, its peak intensity was 1016 W cm−2, its duration was 50 fs and, extrapolated azimuthally, its energy was 0.3 mJ. The simulation followed the amplification and divergence of the short seed pulse for 22.4 ps (a propagation distance of 6.7 mm). The seed started close to the non-linear stage.

The development of the seed pulse intensity envelope is shown over three time-steps in Fig. 3. The pulse starts at its focus, then amplifies as it diverges. Because its amplitude decreases, the long-pump pulse is only visible on the colour scale in the first time-step.

Fig. 3
figure 3

Results of the two-dimensional particle-in-cell simulation. The intensity envelope of the diverging amplified pulse is shown at three time-steps in the simulation, at a 0 ps, b 11.2 ps and c 22.4 ps. The plasma was uniform with density 1019 cm−3 and the pump amplitude (visible on this colour scale only at the first time-step) decreased a0 1/\(\sqrt {t - t_{\mathrm {f}}}\). The pulse propagates towards the right and it has been smoothed on a wavelength scale using a Gaussian filter

Since the pump pulse intensity is higher on-axis, the pulse duration is slightly shorter in the centre. This leads to some transverse gain narrowing, where the focal angle of the amplified pulse is reduced somewhat. This effect could be minimised by using a pump with a flat-top, rather than Gaussian transverse profile. There are some filament structures that permeate through the ionisation front ahead of the amplified pulse, although their growth saturates.

The development of the peak intensity over time is shown in Fig. 4a. The pulse initially drops in intensity as it diverges, then increases again as the Raman scatter converges to the asymptotic constant intensity solution, as predicted by Eq. (15). The peak intensity should eventually converge to a constant value, although the simulation did not continue long enough to observe this.

Fig. 4
figure 4

Results of the two-dimensional particle-in-cell simulation. a The peak intensity of the amplified pulse, as it develops over the 6.7 mm propagation, starting at the focus. b A line-out (solid line) along the x axis of the final intensity envelope after 22.4 ps, given in Fig. 3c. The prediction of Eq. (15) is also shown with the dashed line. c The development of the energy of the amplified pulse. This was found from the two-dimensional data by assuming azimuthal symmetry

To assess the effect of ionisation on the final pulse wave-front, the phase of the pulse was found as a function of radial distance. It was found to deviate from a parabolic shape by <0.1 radians across the transverse width of the pulse. The corresponding radius of wave-front curvature was 6.2 mm, similar to the expected curvature of 6.7 mm for a Gaussian pulse in vacuum.

Figure 4b shows a line-out of the pulse envelope along the x axis, at the final time-step after 22.4 ps. As predicted, there are no secondary trailing peaks. Although, suppression of these peaks is also possible when the pump exceeds the threshold wave-breaking intensity35,36,37,38,39, here this was only true for the first 20% of the propagation. We therefore attribute the suppression to the divergence of the pulse, rather than premature breaking of the plasma wave.

Also plotted with a dashed line in Fig. 4b is the prediction of Eq. (15). Since the simulation used a 2D geometry, the predicted convergent pulse amplitude is twice that of the 3D derivation. This explains why the intensity of the simulated pulse exceeds the 3D prediction. However, the shape of the temporal envelope is accurately reproduced.

In Fig. 4c, the energy of the amplified pulse is plotted as a function of the propagation distance. This was calculated by assuming azimuthal symmetry about the x axis and integrating the intensity profile. Although the intensity is approximately constant, the energy of the pulse increases by a factor of more than 4000. The overall pump to seed energy efficiency was 59%. This value is very high because the amplifier started in the non-linear stage from the beginning and the pump pulse was predominantly below the threshold wave-breaking intensity.

Discussion

Seed pulses in typical Raman amplifier experiments are not intense enough to reach the non-linear stage from the start, so there must first be a long stretch of the amplifier in the low efficiency linear stage. This lowers the overall efficiency. We propose that this stage can be avoided by starting the amplifier at the focus, maximising the effectiveness of the seed. Although some previous studies have used small spot sizes in plasma wave-guides40, 41, the allowable pump energy is then constrained by the small plasma volume. The new diverging geometry increases the allowable pump energy while retaining the minimal seed pulse requirements.

We have shown that if the pump pulse power increases linearly with time, the seed has constant intensity as it amplifies and diverges. In fact, the usual trailing secondary spikes of the standard solution are eliminated, concentrating more energy in the front-most spike. The geometry also enables easy use of the seed ionisation scheme, which has many further advantages. Furthermore, unlike the collimated case, the seed never reaches relativistic intensity and so de-tuning due to the relativistic electron non-linearity is avoided.

The geometry offers a route to scale up the amplifiers to use nanosecond long-pump pulses, as discussed in ref.26. The design could utilise a multi-kilojoule pump pulse with a sub-millijoule seed to reach unprecedented pulse powers. The growth of a 0.3 mJ seed has been simulated to over 1.2 J, with the only eventual limitation set by competing instabilities such as Raman forward scattering and filamentation of the amplified pulse.

Methods

Computer simulation algorithm

The simulation used the particle-in-cell code Osiris, version 2. The grid was Cartesian in two dimensions. The main loop of the algorithm repeats a process that advances the plasma by a finite time-step. First, it interpolates the charge and current densities of a large number of particles to a spatial grid. The grid resolves the Debye length, along with the electromagnetic and plasma wavelengths. The electric and magnetic fields are known on the grid and are advanced in time using the Maxwell equations. The fields are interpolated to the position of each particle and used to update their momentum and position.

As such, the development of the pulse is found directly from the Maxwell equations and all particle trapping effects are modelled in the simulation42. Collisional damping is not modelled in the simulation, however the pump will be largely unaffected because the plasma is only ionised at the position of the short seed pulse. The inverse collisional damping rate is much longer than the seed pulse, so inclusion of collisional damping should barely change the interaction. The domain moved with the amplified pulse at a velocity 0.994c, by initialising new cells at the front of the domain and deleting those at the rear. The pump pulse was also initialised at the leading edge. The laser pulses were initialised as perfect Gaussian beams.

Analysis of the computer simulation

Initially the pump pulse ionised the plasma, but after 1 mm the pump pulse beam waist was wider and it was below the ionisation intensity. From here onwards, the plasma was ionised by the seed pulse. Plasma instabilities of the pump pulse across the 1 mm region near the focus were not modelled. If the pump pulse is excessively degraded by instabilities in this region, it could be reduced in size by increasing the focal angle.

The grid resolution was λ0/60 by λ0/2 transversely. There were 32 electron particles per cell and the ions were held static to reduce computational costs. The simulation used open boundary conditions and cubic particle interpolation. The pulses had aligned linear polarisation.

The pulse envelope was extracted by saving the electromagnetic energy density in each cell at intervals of 280 fs, then smoothing the data on a wavelength scale using a 2D Gaussian filter. The simulated energy of the pulse was extracted by taking the data on only one side of the x axis, assuming the pulse is axially symmetric, then integrating radially and longitudinally using the Jacobian for cylindrical coordinates to obtain the volumetric integral. The total energy efficiency was found by integrating the final seed pulse energy density in two dimensions to obtain a quantity with units J cm−1. The equivalent figure for the pump was found by integrating the unperturbed pump energy density across the simulation domain, then multiplying by the ratio of the pump pulse length to the length of the simulation domain, since the simulated pump power was constant. The overall simulated efficiency is the ratio of these values.

Data availability

The Osiris particle-in-cell code is available on application to the Osiris consortium at: www.picksc.idre.ucla.edu. The simulation set-up files and output data are available on request to P.A.N. E-mail: peter.norreys@physics.ox.ac.uk.