2 Principle

The schematic layout of the proposed technique is shown in Figure 1. This scheme is based on the HGHG setup. First, the electron beam interacts with the seed laser in the modulator. The seed properties such as the transverse phase dependence are imprinted onto the electron beam. When the electron beam passes through the chicane, the energy modulation is converted into a coherent density modulation rich in harmonic content. The second undulator is tuned to a higher harmonic of the seed laser, causing the electron beam to emit coherent radiation at a shorter wavelength.

Figure 1 Scheme to generate an optical vortex with multiple topological charges based on an HGHG setup.

The relative transverse phase changes of the seed laser after passing through the phase mask as shown in Figure 1 can be represented as a matrix:

(1)$$\begin{align} \textrm{Phase}_{\mathrm{mask}}=\left[\kern-4pt\begin{array}{cccc}\frac{3\pi }{2}& \pi & \frac{\pi }{2}& 0\\ {}0& \frac{\pi }{2}& \pi & \frac{3\pi }{2}\end{array}\kern-4pt\right]. \end{align}$$

Each number in this matrix represents the phase value at each interval $\frac{\pi }{4}$ radians azimuth position. In a short modulator, the electron beam interacts with the seed laser which travels through the phase mask. The transverse eight-step phase structure is imprinted onto the electron beam. The electron beam phase structure can also be represented as shown in Equation (1).

After the electron beam passes through the dispersion section, the above energy modulation is converted into a coherent microbunching. The transverse phase of microbunching can be represented as in the matrix in Equation (1). According to the frequency up-conversion theory of HGHG^[Reference Yu^18], the transverse phase structure of the electron microbunching at the radiator entrance can be interpreted as the following matrix:

(2)$$\begin{align} \textrm{Phase}_{\mathrm{rad}}=n\cdot \textrm{Phase}_{\mathrm{ebeam}}=n\cdot \left[\kern-4pt\begin{array}{cccc}\frac{3\pi }{2}& \pi & \frac{\pi }{2}& 0\\ {}0& \frac{\pi }{2}& \pi & \frac{3\pi }{2}\end{array}\kern-4pt\right]\operatorname{mod}2\pi,\end{align} $$

where $n$ is the harmonic number. The final electron microbunching structure will be different for different values of $n$. For the case where $n$ is an even number, the electron microbunching structure can be represented as

(3)$$\textrm{Phase}_{\mathrm{rad}}=\begin{bmatrix}0 & 0 & 0 & 0\\0& 0& 0& 0\end{bmatrix}\left(n=4m\right),$$

and

(4)$$\textrm{Phase}_{\mathrm{rad}}=\begin{bmatrix}\pi & 0& \pi & 0\\ {}\pi & 0& \pi & 0\end{bmatrix}\left(n=4m+2\right).$$

It should be noted that after up-conversion, the phase jump of each step in the microbunching is 0 or $\pi$ when $n$ is an even number. However, this phase structure is not suitable for generating an optical vortex. When $n$ is an odd number $n=2m+1$, the electron microbunching structure can be represented as

(5)$$\begin{align}\textrm{Phase}_{\mathrm{rad}}=\left[\kern-4pt\begin{array}{cccc}\frac{3\pi }{2}& \pi & \frac{\pi }{2}& 0\\ {}0& \frac{\pi }{2}& \pi & \frac{3\pi }{2}\end{array}\kern-4pt\right]\left(m:\mathrm{even}\right),\end{align}$$

and

(6)$$\begin{align}\textrm{Phase}_{\mathrm{rad}}=\left[\kern-4pt\begin{array}{cccc}\frac{\pi }{2}& \pi & \frac{3\pi }{2}& 0\\ {}0& \frac{3\pi }{2}& \pi & \frac{\pi }{2}\end{array}\kern-4pt\right]\left(m:\mathrm{odd}\right).\end{align}$$

For the case of odd $n$, it can be shown that the final transverse phase of e-beam increases in the opposite direction for different values of $m$. According to the above theory, the electron beam will emit light with an eight-step structure in the radiator entrance at a high odd harmonic of the seed laser. According to the analysis, the eight-step phase mask can be created for seed laser shaping and, hence, for fine transverse shaping of the electron beam in the modulator. In general, the phase of the microbunching is constant in the transverse plane. In this scheme, the transverse phase of the microbunching is an eight-step structure which has a helical bunching component at high harmonic frequency. Therefore, the radiation emitted by the special electron beam will develop into the optical vortex along the radiator.

3 The principle of phase mask shaping

The optical setup for the seed laser in the proposed scheme is shown in Figure 2, where the seed laser is focused through a lens immediately after passing through the phase mask and finally injected into the undulator to interact with the electron beam.

Figure 2 Optical setup in this scheme.

The transport processes of the seed laser can be studied with the wave optics^[Reference Goodman^26]. The optical field after the phase mask is $\tilde{E}\left({x}_1,{y}_1\right)$. The complex optical field after lens is given by the following formula

(7)$$\begin{align}{\tilde{E}}^{\prime}\left({x}_1,{y}_1\right)=\tilde{E}\left({x}_1,{y}_1\right)\exp \left[-\frac{ik}{2f}\left({x}_1^2+{y}_1^2\right)\right].\end{align}$$

Here $f$ is the focal length of the lens and $k$ denotes the wave number of the laser. According to the Fresnel optical propagation theory, the light field after a distance $f$ is

(8)$$\begin{align}E\left(x,y\right)&=\frac{\exp \left({i} kf\right)}{{i}\lambda f}\exp \left[\frac{ik}{2f}\left({x}^2+{y}^2\right)\right] \nonumber\\ & \quad \times \mathrm{\mathcal{F}}\left\{{\tilde{E}}^{\prime}\left({x}_1,{y}_1\right)\exp \left[\frac{ik}{2f}\left({x}_1^2+{y}_1^2\right)\right]\right\}.\end{align}$$

Equation (8) could be mathematically simplified to

(9)$$\begin{align}E\left(x,y\right)=\frac{\exp \left({i} kf\right)}{{i}\lambda f}\exp \left[\frac{ik}{2f}\left({x}^2+{y}^2\right)\right]\mathrm{\mathcal{F}}\left\{\tilde{E}\left({x}_1,{y}_1\right)\right\}.\end{align}$$

The above formula shows that the complex optical field in the focal plane is the Fourier transform of the optical field through phase mask and the complex optical field can remain the eight-step structure in the focal plane. The above equations are written into a program to model and analyze the optical field propagation process. The complex optical field in the focal plane is shown in Figure 3. The transverse phase of the optical field presents a distinct eight-step structure.

Figure 3 (a) Transverse intensity and (b) corresponding phase of seed laser in the focal plane.

In the proposed scheme, the focal plane of the lens is set to the middle of the modulator as shown in Figure 2. According to the propagation theory of wave optics, the optical field distribution after transverse shaping to a certain place is related to the focal length of the previous lens. In addition, the lens can suppress the divergence of the light field near the focal plane. Here, a lens with long focal length exceeding 20  m and a short modulator with length of 50 cm are chosen to maintain the eight-step structure of the laser beam in the modulator.

4 Interaction between the electron beam and the optical field

A three-dimensional algorithm^[Reference Wang, Feng, Tsai, Zeng and Zhao^27, Reference Zeng, Feng, Wang, Zhang, Qi and Zhao^28], which is built based on the fundamental basis of electrodynamics, is modified for simulating the laser–beam interaction in the modulator. The magnetic field distribution of the planar undulator in the y direction can be written as

(10)$$\begin{align}{B}_y={B}_0\sin \left({k}_{\mathrm{u}}z\right),\end{align}$$

where ${B}_0$ is the undulator peak magnetic field, ${k}_{\mathrm{u}}=2\pi /{\lambda}_{\mathrm{u}}$ is the wave number of the undulator, and ${\lambda}_{\mathrm{u}}$ is the period length of the undulator. The results in Section 3 demonstrate that the transverse phase of the complex field near the focal plane can be maintained in an eight-step structure. Thus, the electric field of a seed laser near the focal plane can be represented as

(11)$$\begin{align}{E}_x={E}_0\sin \left[{k}_{\mathrm{s}}\left({z}^{\prime }-{z}_0\right)+\phi \right]\sqrt{e^{-\frac{x^2}{2{\sigma}_x^2}-\frac{y^2}{2{\sigma}_y^2}\frac{{\left({z}^{\prime }-{z}_0\right)}^2}{2{\sigma}_z^2}\frac{}{}}},\end{align}$$

and

(12)$$\begin{align}\phi =\left[\begin{array}{cccc}\frac{3\pi }{2}& \pi & \frac{\pi }{2}& 0\\ {}0& \frac{\pi }{2}& \pi & \frac{3\pi }{2}\end{array}\right],\end{align}$$

where ${k}_{\mathrm{s}}=2\pi /{\lambda}_{\mathrm{s}}$ is the wave number of the seed laser, ${z}_0$ is the initial relative position of the laser from the electron beam, ${E}_0$ is the peak electric field intensity of the seed laser, and $\phi$ is the carrier envelope phase of the seed laser. For the optical field with eight-step transverse distribution, the phase can be represented as the above matrix similar to the transverse phase of the phase mask referred to Section 2. The diffraction effects of the laser field can be expressed by

(13)$$\begin{align}{\sigma}_x(z)=\sqrt{\sigma_{x\mathrm{w}}^2+\frac{k_{\mathrm{s}}^2{\left(z-{z}_{\mathrm{w}}\right)}^2}{4{\sigma}_{x\mathrm{w}}^2}},\end{align}$$

and

(14)$$\begin{align}{\sigma}_y(z)=\sqrt{\sigma_{y\mathrm{w}}^2+\frac{k_{\mathrm{s}}^2{\left(z-{z}_{\mathrm{w}}\right)}^2}{4{\sigma}_{y\mathrm{w}}^2}},\end{align}$$

where ${\sigma}_{x\mathrm{w}}$ and ${\sigma}_{y\mathrm{w}}$ denote the laser size at the longitudinal waist position ${z}_{\mathrm{w}}$. In the undulator, the electron’s motion satisfies the law of the electrodynamics,

(15)$$\begin{align} \gamma {m}\frac{\mathrm{d}\overrightarrow{v}}{\mathrm{d}t}=e\overrightarrow{E}-e\overrightarrow{v}\times \overrightarrow{B}.\end{align}$$

The energy exchange between the electrons and the laser field in the undulator can be represented as

(16)$$\begin{align}{m}{c}^2\frac{\mathrm{d}\gamma}{\mathrm{d} t}={eE}_x\frac{\mathrm{d} x}{\mathrm{d} t}.\end{align}$$

Parameters of the Shanghai Soft X-Ray Free Electron Laser User Facility (SXFEL-UF) are used here for the simulation, as summarized in Table 1. The seed laser originates from a commercial Ti:sapphire laser system, which can provide laser pulses with pulse energy up to 10 mJ at 800 nm. A third harmonic generation (THG) is employed to convert the laser to 266 nm. Even with a conversion efficiency of $10\%$ of the THG, it is easy to achieve a peak power of 10 GW level at 266 nm. Here we adopted a seed laser power of 2 GW in the simulations. With these parameters, the electron beam receives about seven times the energy modulation of its energy spread. The longitudinal phase space after the modulator is shown in Figure 4(a).

Figure 4 (a) Longitudinal phase space of the electron beam after the modulator. The vertical axis p represents the energy modulation amplitude, which is defined as the ratio of the electron’s deviation from the central energy to the initial energy spread. (b) Transverse phase of the local microbunching $b\left({\vec{r}}\right)$.

Table 1 Main parameters of the simulation.

Unlike the common sinusoidal energy modulation of an electron beam, there are several discrete sinusoidal modulations in an optical wavelength with phase delays between them. As shown in Figure 1, the electron beam interacts with the seed laser field which has typical transverse phase structure in the modulator. The seed properties such as the transverse phase dependence are imprinted on the electron beam phase space. Then the electron beam passes through the dispersion section for density modulation where different energy electrons travel different lengths. As a result of this process, the microbunching structure in electron beam is created. Considering the transverse structure of the microbunching, the local bunching factor can be calculated as^[Reference Ribič, Gauthier and De Ninno^23]

(17)$$\begin{align}b\left(\overrightarrow{r}\right)=\left\langle \exp \left[i{\theta}_i\left(\overrightarrow{r}\right)\right]\right\rangle .\end{align}$$

Here, ${\theta}_i$ is the pondermotive phase of the ith particle and the brackets represent the ensemble average over all the particles at a given transverse position $\overrightarrow{r}$ in the electron beam. Figure 4(b) illustrates the transverse phase of the local microbunching factor $b\left(\overrightarrow{r}\right)$, where the transverse phase of the microbunching is not constant but has an eight-step structure.

5 FEL performance

The FEL radiation is simulated with the three-dimensional time-dependent FEL simulation code Genesis 1.3^[Reference Reiche^29]. The radiator is resonant at the seventh harmonic of the seed laser, which is 38 nm. The microbunched electron beam as shown in Figure 4(b) is sent into the radiator with proper lattice arrangement for FEL simulation. As illustrated in Figure  5(a), the coherent radiation produced by the modulated electron beam retains the eight-step structure at the radiator entrance. Consequently, the evolution of the radiation profile is primarily governed by the diffraction and linear field amplification. Then, the radiation profile gradually evolves from an eight-step structure to a ring-like distribution with helical transverse phase. At the radiator exit, the radiation profile changes to a typical vortex light profile with topological charge 2 and the radiation power is saturated. To illustrate the evolution of electron beam in the radiator, the helical bunching factor has been illustrated in Figure 5(b) according to the approaches mentioned in the paper^[Reference Hemsing and Marinelli^24]. The electron bunching factor at the azimuthal mode $l$ is denoted by

(18)$$\begin{align}{b}_l(k)=\bigg|\bigg\langle {e}^{-{ikz}^{\prime\prime}- il\phi}f\left({\mathbf{x}}_{\perp },z,p\right)\bigg\rangle \bigg|,\end{align}$$

Figure 5 (a) Evolution of the power along the radiator. (b) Evolution of the bunching factor along the radiator. (c) The longitudinal power and (d) its spectrum at the radiator exit.

where $f\left({\mathbf{x}}_{\perp },z,p\right)$ is the electron beam distribution and brackets indicate averaging over the ultimate coordinates, and ${\mathbf{x}}_{\perp}=\left(r,\phi \right)$ represents the radial and azimuthal coordinates. Here, $k$ is the harmonic frequency, $z$ is the longitudinal position of the electron beam, and $p$ is the energy modulation amplitude:

(19)$$\begin{align}p=\left(E-{E}_0\right)/{\sigma}_{\textrm{E}}.\end{align}$$

where ${E}_0$ is the central beam energy and ${\sigma}_{\textrm{E}}$ is the rms energy spread. As shown in Figure 5(b), ${b}_2$ is always dominant in the radiator and ${b}_0$ and ${b}_1$ are suppressed. Consequently, this allows the optical vortex with topological charge 2 to dominate the radiation in the mode competition along the radiator. The radiation with topological charges 1 and 0 is suppressed in the radiator. Figures 5(c) and 5(d) show the longitudinal profile of the radiation pulse and the corresponding spectrum at the radiator exit. The simulation results show that 100-MW, fully coherent EUV vortex pulses with topological charge 2 at 38 nm can be generated at the exit of radiator. Figure 6 shows the final transverse intensity and its corresponding phase of radiation at the radiator exit. It can be clearly seen that the transverse intensity distribution of the light presents an obvious ring-like profile, and the transverse phase distribution has the typical characteristics of vortex light with topological charge 2.

Figure 6 (a) The transverse intensity and (b) its corresponding phase of radiation at the radiator exit.

6 Generation of vortex light with higher topological charges

The phase mask shaping technique is also suitable for the generation of vortex light with higher topological charges. Here we take a phase plate with 12 steps as an example to show the generation of vortex beam with topological charge 3 at 38 nm. Simulation results are given in Figure 7. By using an undulator segment with length of 4 m, vortex radiation pulse with peak power over 10 MW can be generated. The transverse phase distribution has the typical characteristics of vortex light with topological charge 3, as shown in Figure 7(b). However, it should be noted that the vortex light with topological charge 3 can hardly be amplified to saturation due to the weaker transverse coupling between the electron beam and the vortex light with greater emission angle^[Reference Hemsing and Marinelli^24].

Figure 7 (a) Evolution of the power along the radiator. (b) The transverse phase of radiation at the radiator exit.