3.1. European XFEL and the SASE2 undulator source

The European XFEL is a free-electron laser (FEL) user facility currently delivering soft and hard X-ray FEL radiation to six scientific instruments (Tschentscher et al., 2017). It provides X-rays with high average brilliance and extreme peak intensities at photon energies up to 25 keV in the fundamental, with femtosecond pulse duration and a high degree of coherence. The high average brilliance is achieved through acceleration of up to 2700 electron bunches with typically 0.25 nC at a 10 Hz repetition rate by a superconducting electron accelerator (Weise & Decking, 2017) (Fig. 1). After reaching energies of 11.5, 14, or 16.5 GeV, these electrons are distributed to three beamlines housing self-amplified spontaneous emission (SASE) undulators (Abeghyan et al., 2019) with horizontal polarization. Tuning of the photon energy is achieved independently in each beamline by adjusting the undulator gaps. The HED science instrument is located after the SASE2 undulator which produces short ∼25 fs X-ray pulses with photon energies from 5 to 25 keV (Scholz & Zhao, 2019).

Figure 1 Unique bunch pattern of European XFEL. Within an up to 600 µs-long window, between a single and 2700 X-ray pulses can be created. The facility can deliver pulses at difference repetition rates of 4.51, 2.26, or 1.13 MHz, resulting in a pulse spacing of 222, 443 or 886 ns, respectively.

The highest achieved SASE2 levels are summarized in Fig. 2 – average performance is at 50–80% of these values. Typically, a SASE spectrum has a fully tunable Gaussian spectral envelope with bandwidth ΔE/E ≃ 10⁻³. Within this bandwidth, the spectrum consists of several longitudinal modes leading to <1 eV broad spikes which statistically fluctuate from pulse to pulse. Example spectra are shown in Section 4.2.2. SASE2 can also operate in hard X-ray self-seeding mode (HXRSS) (Geloni et al., 2011, 2019; Liu et al., 2019), producing a more coherent and narrow-bandwidth pulse. Current studies performed at 7.5 and 9 keV photon energy yield pulse energies of ∼1 mJ in a spectral bandwidth of ∼1 eV.

Figure 2 Current peak performance of the SASE2 FEL at photon energies between 6 and 18 keV. The data points represent peak pulse energies measured in 2019 and 2020 (https://xfel.desy.de/operation/performance/; see also Maltezopoulos et al., 2019). The linac was operated at 11.5 GeV (blue crosses), 14 GeV (black rectangles) and 16.5 GeV (red circles) electron energy.

The initial beam divergence from the undulator can be measured using imagers along the beam transport, which in turn allows to estimate the diffraction-limited source size as a function of photon energy, as shown in Table 1.

3.2. HED instrument layout

The HED instrument is located in the experiment hall at the end of a ∼970 m-long photon beam transport tunnel partially shared with the Materials and Imaging Dynamics (MID) instrument (Madsen et al., 2021). The basic layout of the HED hutches is described in the Technical Design Report (TDR) (Nakatsutsumi et al., 2014) and the layout of the optics and experiment hutch is shown in Fig. 3.

Figure 3 HED optics and experiment hutch layout. The X-rays enter from the right. Optics hutch: PSLIT – water-cooled four-blade power slits, BIU – beam imaging unit, PAM – photon arrival monitor for X-ray-optical laser timing, ATT – solid attenuator foils, CRL – compound refractive lenses made of Be (CRL3), IPM1 – intensity and position monitor. Experimental hutch: ALAS: incoupling for alignment laser, DPS – differential pumping, CSLIT – clean-up slits, two four-blade assemblies for soft and hard X-rays, respectively, IPM2 – intensity and position monitor, IC1 and IC2 – interaction chambers, AGIPD – MHz repetition compatible X-ray detector, DBENCH – detector bench, SPECTRO – position of downstream spectrometers, IBS – instrument beam stop. The distances on the top are given from the source (center of last undulator segment).

The experiment hutch and the optics hutch are air-conditioned and H14-filtered and kept at a temperature of 21 ± 1°C and a humidity of 50 ± 2.5%. Dedicated zones exist with precision temperature control: 21 ± 0.1°C. Details of the experiment hutch arrangement are described in Section 6. On the roof of the experiment hutch is a laser bay which houses the two large laser systems ReLaX and DiPOLE (see Fig. 4 and Sections 5.3.1 and 5.3.2) in a clean-room-like laboratory with precision temperature (21 ± 0.1°C) control. Adjacent to this are rack rooms where the majority of the control electronics and power supplies are placed.

Figure 4 Schematics showing the position of the ReLaX and DiPOLE 100-X laser in a room above the experiment hutch with the interaction chambers IC1,2 (walls not shown).

3.3. Control systems

The European XFEL's Python-based software framework for control and data acquisition is named Karabo (Heisen et al., 2013). It allows the user to build extendable distributed applications that can be remotely controlled through a graphical user interface (GUI) or command line interface. While acting as a control system, Karabo interfaces with hardware controllers via driver devices. The communication between the Karabo devices as well as instrument- and experiment-specific programming can be implemented in so-called Karabo middle layer devices and macros (Hauf et al., 2019).

The control hardware can be divided into two categories: slow real-time control (motion control, vacuum system, water flow and temperature control) and fast electronics for timing and analog-digital conversion. The slow real-time control is managed by an industrial standard Programmable Logic Controller (PLC) system based on EtherCAT bus terminals and CPUs from Beckhoff (Gessler et al., 2020) enhanced by multi-channel-Piezo motion controllers with interlock capability that are directly interfaced to the Karabo control system.

The use of the industrial PLC system facilitates standardization and modularization of software and hardware. It also allows the implementation of equipment protection interlocks, motorized axis coupling, and feedback control. The fast electronics platform uses MicroTCA crates for timing, digitization of analog signals, and online signal processing (Gessler et al., 2020) which matches the pulse rate of European XFEL.

The timing precision performance of the Karabo-controlled software layer is typically well below the 100 ms, but high network traffic can cause latency. Therefore, for 10 Hz pulse-to-pulse actions such as triggering an acquisition, the real-time PLCs are preferred. Sampling of data within the pulse train with 222 ns intervals, or even resolving sub-ns pulse shapes, is possible using the the MicroTCA with sampling rates of up to 0.5 Gigasamples s⁻¹.

4.1. X-ray focusing optics

The X-ray focusing is based on Be CRLs (Lengeler et al., 1999). These optics are chromatic, which requires different lens configurations for each photon energy (Zozulya et al., 2019; Nakatsutsumi et al., 2014).

Three groups of lenses are placed at different positions along the HED beamline (labeled CRL1-3) in order to ensure the maximum throughput of photons by matching the aperture to the FEL beam size. Several focal schemes and the lens configurations are shown in Appendix B. Depending on photon energy and not taking into account the chromatic aberration due to the finite SASE bandwidth, the smallest FWHM beam sizes that can be theoretically achieved at the target chamber center (TCC) are 150–250 µm with CRL1, ∼15 µm with CRL2 and 1–2 µm with CRL3. The CRL2 is placed after the monochromators in order to keep the divergence over the monochromators low.

Since the lenses are chromatic, a SASE spectrum will be focused across a finite range. Table 2 compares the Rayleigh length of the monochromatic beam with the actual focal length spread according to 0.3% FWHM spectral bandwidth using an intermediate focus with CRL1 and subsequent tight focusing with CRL3. The entire chamber of CRL3 can be translated by ±50 cm along the beam axis to overlap focal positions and TCC.

In order to characterize the shape and size of the X-ray focus, single-pulse imprints in lithium fluoride (LiF) creating permanent point-defects (Pikuz et al., 2015) were taken and yield a focal spot of 4–5 µm FWHM at 6 keV with SASE beam (Fig. 7). Due to chromatic aberration, the Rayleigh range extends over several tens of mm.

Figure 7 Characterization of the best focus of CRL3 and an intermediate focus scheme with CRL1 at 6 keV photon energy. The three false-color insets are single-shot imprints into a LiF crystal at 0.5% beamline transmission.

Alternatively, scanning methods with an obstacle project the focal size along the scan direction. Figure 8 shows the results of scanning the round edge of a 1 mm-diameter tungsten wire across the focused X-rays at 17.8 keV, resulting in a 4.5 µm × 5 µm spot (FWHM). While providing immediate focal size estimates, the result is potentially broadened by beam pointing jitter.

Figure 8 Characterization of the best focus of CRL3 after intermediate focus with CRL1 at 17.8 keV with a wire scan. The scans took a few minutes with 5% transmission. The y-axis shows in red the transmission (normalized to the incident pulse energy, and with a moving average), as well as its derivative in blue.

In order to reach X-ray foci smaller than 1 µm, both interaction chambers can be equipped with CRLs with adjustable short-focal length between about 10 cm and 1 m. This nano-focusing capability (CRL4) is contributed by the HIBEF UC. These lenses have radii of curvature of 50 µm, an effective aperture between 300 µm and 400 µm, and up to 50 of them can be hosted in a lens cassette, similar to the concept described by Schropp et al. (2012). Slight pre-focusing is necessary to match the aperture and achieve maximum throughput.

A focus spot size of ∼220 nm at the TCC of IC1 has been demonstrated using a SASE beam at 9 keV photon energy. The average focus size was retrieved from scanning ptychography (Schropp et al., 2013) and yields an upper limit of 220 nm FWHM for a monochromatic beam and ≤300 nm FWHM for SASE. For the SASE case, we could not resolve a difference between a ten-shot average and a single exposure, indicating a focal jitter of less than ∼500 nm.

4.2. X-ray monitors and diagnostics

4.2.2. Bent crystal spectrometers

The stochastic nature of the SASE process results in spectral fluctuations from pulse to pulse. In order to record a single pulse-resolved spectrum, the use of cylindrically bent Si crystals has been practiced widely (Zhu et al., 2012) as a transmissive Bragg spectrometer, albeit its application is limited to a few tens of pulses at MHz repetition rates. A recent development using cylindrically bent diamond crystals has shown comparable spectral resolution (Boesenberg et al., 2017; Samoylova et al., 2019) and radiation tolerance for full 4.5 MHz pulse trains at 9 keV photon energy. There are three opportunities for inserting such spectrometers into the beam path, all of them equipped with both diamond and Si crystals with various bending radii and cuts.

Upstream of the sample, the HIREX-II (Kujala et al., 2020) spectrometer is permanently installed between mirrors M2 and M3. It covers the photon energy range 5–25 keV at a resolution of ≤0.2 eV. The reflected signal can either be recorded with a 10 Hz 2D sCMOS detector, or at 4.5 MHz with a 1D X-ray GOTTHARD detector (Mozzanica et al., 2012). For experiments that require the spectral information right up- or downstream of a sample, additional bent-crystal spectrometers HED-flex and CNRS-spec can be placed simultaneously. The CNRS-spec [contribution from Center National de la Recherche Scientifique (CNRS), France] can flexibly be placed inside or outside the IC1 chamber, while the HED-flex can be placed in-air downstream of IC1. Both the HED- and CNRS-spec are designed to be inserted directly in the beam, similar to the HIREX-II spectrometer. Both are also coupled with either a 10 Hz 2D optical camera or a 1D GOTTHARD X-ray detector. The HED-flex spectrometer has been tested at 6 keV in the diverging beam (see Fig. 9) using Si(111) crystal with 78 mm bending radius, and a 10 Hz ANDOR sCMOS ZYLA 5.5 camera, imaging a 25 µm YAG:Ce screen, with a magnifying microscope objective. The minimum energy resolution for this arrangement was 0.13 eV.

Figure 9 Examples of single-pulse spectra. Spectra as recorded by a 2D detector imaging a scintillator screen (top) and their corresponding lineouts (bottom). Left: HED-flex at 6 keV using a Si(111) crystal and lineouts of three different pulses to illustrate the shot-to-shot fluctuation. Right: HIREX-II in the XTD6 tunnel at 17.5 keV using C(110).

A detailed description of the spectrometer configurations can be found in Appendix B.

4.3. Monochromators

An Si(111) four-bounce monochromator (Dong et al., 2016) consisting of two pairs of artificial channel-cut crystals can be inserted into the beam path. It reduces the bandwidth to ΔE/E ≃ 1 × 10⁻⁴ (Fig. 10) for the complete range of photon energies. Both pairs of crystals can be cryogenically cooled to mitigate the heat load during a pulse train. The second pair of the Si(111)-monochromator can be replaced with a Si(533) channel-cut crystal, yielding a bandwidth of ΔE/E ≃ 4 × 10⁻⁶ at a fixed photon energy of 7494 eV. More details are given by Wollenweber et al. (2021). Both configurations provide zero offset between the incident and the monochromated beam. In order to keep the beam divergence on the crystals small, the monochromators are positioned upstream of the CRL2 and CRL3 optics. The beam jitter after the cryogenically cooled Si(111) monochromator was measured by the imager screen at the end of the XTD6 tunnel, 22 m downstream of the monochromator, to be ∼40 µm in both horizontal and vertical.

Figure 10 Measured energy resolution of the Si(111) monochromator at E = 6055 eV. The transmitted SASE X-ray pulse energy of the four-bounce setup is shown as a function of the Bragg angle (scaled to photon energy) of the second pair of crystals while the first pair was fixed. The Gaussian fit yields a FWHM of ΔE = 0.72 eV and ΔE/E ≃ 1.2 × 10−4.

4.4. Slit systems

The HED instrument includes three sets of slit systems to control the size of the beam and its potential halo. Such a halo can be caused by scattering from upstream slits, apertures, screens or filters. The water-cooled power slits are the first device located in the optics hutch, ∼15 m upstream of the TCC in IC1, and this system comprises four independent, non-intersecting slits with travel ranges of ±25 mm. The slits are 5 mm blades of tungsten carbide bonded to an absorbing block of 70 mm-thick B₄C. The blades have highly polished knife-edges with a slope of 0.5° and can be positioned with an accuracy of 0.4 µm.

In the experiment hutch ∼2 m before the TCC of IC1, there are two sets of clean-up slits, consisting of non-intersecting blades with travel ranges of ±15 mm. These can clean up potential scattering introduced by the first slit system and the CRLs. The first pair is similar to the power slit: it uses 4 mm tungsten carbide blades, with a highly polished 0.5° knife-edge, mounted to 6 mm-thick B₄C absorbers. The second pair, however, provides a round edge made from Si₃N₄ and mounted to a 3 mm tantalum blade. These slits can also be positioned with an accuracy of <1 µm.

The clean-up slits can also be used to decrease the content of higher harmonics in the beam, which is typically less focused near the TCC due to the chromaticity of the CRLs.

4.5. Attenuators and pulse picker

Solid attenuators are placed in the HED beamline at two positions. The upstream attenuator is positioned in the common SASE2 branch, downstream of the first XGM and upstream of the beamline optics (see Fig. 5). It comprises six chemical vapor deposition (CVD) diamonds (0.075–2.4 mm thick) and three Si filters (0.5–2.0 mm thick).

The second attenuator at HED is installed just upstream of the CRL3 optics in the HED optics hutch. Here the filters are mounted on four motorized arms which hold six attenuators each. These 24 filters are either Si or CVD diamond with varying thicknesses (0.025 mm–6.4 mm for Si and 0.1 mm–1.6 mm for CVD diamond). A wide range of transmissions can be achieved by the insertion of filters in up to four arms simultaneously.

The pulse picker unit (PPU) can pick pulse trains at a maximum repetition rate of 10 Hz. It is positioned just downstream of the HED XGM and consists of a rotating chopper disk made from a sandwich of 2 mm B₄C and 3 mm Densimet with several openings across its circumference. This disk is rotated by a fast DC motor.

5.1. Intense X-ray pulses

Assuming a typical performance of the SASE2 undulator at 6–10 keV of 2 mJ pulse energy (reduced to ∼1 mJ at the TCC due to the overall beamline transmission) in a duration of 25 fs allows to create power densities, or peak intensities, in excess of 10¹⁷ W cm⁻² when focused to 5 µm FWHM. These intensities volumetrically excite solid-density matter at timescales shorter than a phonon period, and predominantly couple to certain atomic orbitals when the photon energy is chosen with respect to resonances or absorption edges (Vinko et al., 2012; Sperling et al., 2015; Yoneda et al., 2015).

Using the nanofocus setup, the diffraction-limited spot sizes and resulting intensities for a stack of Be CRLs with radii of curvature of 50 µm and 300 µm geometric aperture, a monochromatic (seeded) beam at 9 keV, 500 µJ pulse energy (accounting for the upstream beamline transmission) are as given in Table 3.

While the achievable intensities are ten times higher than using CRL3, the excited volume is small and comparable with the mean free path of photo- and Auger electrons which will rapidly redistribute the deposited energy. The photon-energy-dependent transmission can be calculated by equation (48) of Lengeler et al. (1999) and depends on the absorption properties of the lens material and the related effective numerical aperture.

A unique possibility of European XFEL is X-ray excitation of a sample with a MHz X-ray burst. Free-standing or statically compressed samples (e.g. in a DAC) can be sequentially and volumetrically heated and simultaneously probed by X-ray techniques (cf. Section 7).

While the delay between two subsequent pulses from the accelerator is limited to 222 ns, in the near future the HED instrument will also provide two-pulse techniques with separations <1 ps, either by two-color SASE with an electron chicane or by using an X-ray split-and-delay line (Mitzner et al., 2008; Wöstmann et al., 2013; Roling et al., 2017; Kärcher et al., 2021).

5.2. Diamond anvil cells

The provision of X-ray photon energies >10 keV enables the HED instrument to perform experiments in DACs. The DAC setup in the IC1 chamber is suited for emission spectroscopy-type experiments (Section 6.2.6), whereas the one in IC2 provides a dedicated platform for MHz X-ray diffraction in dynamic DAC compression and heating experiments (Sections 6.4 and 6.4.1) which are described in detail by Liermann et al. (2021). High temperatures (typically in the range 1000–10000 K) are generated either via double-sided pulsed laser heating or by X-ray heating, the latter by varying the repetition rate of the X-ray pulses within a train. Dynamic compression is achieved in a piezo-driven dynamic DAC (dDAC) capable of compressing samples to megabar pressures on a millisecond time scale (Jenei et al., 2019), enabling the study of material behavior under intermediate strain rates between those achieved in static and shock compression experiments. In dynamic, laser-driven shock compression experiments, DACs can also be used to precompress materials in order to reach higher pressures at moderate temperatures which are not accessible by shock-compressing materials from ambient pressures (Brygoo et al., 2015; Loubeyre et al., 2012).

5.3. Optical lasers

5.3.2. DiPOLE 100-X laser

The High Energy laser DiPOLE 100-X (Diode Pumped Optical Laser for Experiments) is an all diode-pumped 100 J class ytterbium:YAG based laser, manufactured by STFC CLF (Central Laser Facility) in the UK and the University of Oxford as part of the UK's contribution to the HIBEF UC (Phillips et al., 2019). The laser system delivers 100 J for a 10 ns pulse duration and 37 J for a 2 ns pulse duration at the fundamental wavelength (1030 nm). In addition it is capable of 10 Hz operation resulting in kW output of optical light. Since the main scientific use of DiPOLE 100-X is laser-driven shock and ramp compression, the laser provides pulse shaping capabilities with a resolution of 125 ps, allowing arbitrary waveforms ranging in duration from 2 to 15 ns. Frequency doubling of the 1030 nm laser to 515 nm with 60 J at 10 Hz for a 10 ns pulse has been demonstrated using a 60 mm large aperture lithium-triborate (LBO) crystal (Phillips et al., 2021); conversion efficiencies for a 2 ns pulse are expected to be similar. The laser is synchronized with the X-ray beam using the XFEL timing system which has an RMS jitter of approximately 10 ps. The temporal total temporal jitter of the laser beam against the X-ray beam including all components is not yet characterized, but expected to be better than 50 ps. We also plan an online monitoring of the arrival time of both laser and X-rays. Phase plates providing flat-top focal spot profiles ranging from 100 to 500 µm diameter shall be provided. The DIPOLE 100-X laser will be available in both IC1 and IC2 with irradiation ranging from close to co-propagation (22.5°) to perpendicular.

The full capabilities of DiPOLE 100-X can be exploited in combination with the HIBEF-provided VISAR (see Section 6.7.1) system and the high-precision XRD platform at IC2 (see Section 6.4). The DiPOLE 100-X laser was delivered to European XFEL in 2019 and is currently being commissioned. The first user experiment is scheduled for 2022. Fig. 11 shows both the ReLaX and DiPOLE 100-X lasers in the laser bay.

Figure 11 View into the HED laser bay with both HIBEF high-power lasers DIPOLE 100-X (left) and ReLaX (right).

5.3.4. Synchronization of optical lasers and XFEL pulses

The optical lasers ReLaX, DiPOLE, and PP require spatial and temporal synchronization with the X-ray pulses which places high demands on environmental stability and an extensive online diagnostics. The linear accelerator provides pulses according to its own timing, and the various laser sources need to be synchronized relative to it. When lasers are synchronized using the accelerator's radiofrequency only, a jitter of about 300 fs is observed (Kirkwood et al., 2019). To improve on this, a Master-Laser-Oscillator (MLO) provides a more stable timing reference. A dispersion-compensated, actively stabilized optical fiber link synchronizes the individual oscillators of the ReLaX and PP laser on a sub-10 fs level. Nevertheless, the subsequent amplification process in both the FEL and the optical lasers and their long beam transport will lead to additional timing jitter and long-term temporal drift. Therefore, a pulse-resolved online photon arrival monitor (PAM) is implemented to record the relative arrival time between the optical and the X-ray pulses at the 10 Hz repetition rate. The PAM is permanently installed about 10 m upstream of the IC1 sample position in the optics hutch, before the X-ray attenuator and CRL3. This allows the jitter measurements to be quasi-independent from the X-ray focusing scheme and attenuation level which may be varied during experiments. The obtained data can be later used for time-sorting and binning. The typical sample is Si₃N₄ with 2 µm thickness. This ensures a high X-ray transmittance (>90% at >5 keV and >97% at >8 keV) for experiments downstream. The PAM consists of two sample chambers which allows simultaneous measurements using spatial (Harmand et al., 2013; Riedel et al., 2013) and spectral encoding (Bionta et al., 2011) (Fig. 12) methods. While spatial encoding provides a better signal-to-noise ratio, the spectral encoding appears to be more robust against X-ray pointing fluctuations. To ensure that PAM works at different X-ray photon energies, Si₃N₄ of 4 and 6 µm thickness and a high-Z material sample (e.g. YAG:Ce 10, 20 µm thicknesses) are available, and are interchangeable during experiments.

Figure 12 Typical images of PAM. (a) Spatial encoding: vertical versus horizontal position; time mapping results form an angle between the laser and the X-ray on the sample (2 µm-thick Si3N4). The temporal window (horizontal) is about 3.6 ps. (b) Spectral encoding image: lateral position versus the wavelength mapped to time by a chirped laser pulse collinear with the X-ray perpendicular to the sample (100 µm-thick YAG:Ce). The temporal window (horizontal axis of the image) is about 1.7 ps. Both show a shadow due to the X-ray-induced opacity change of the sample. At t0 both beams are timed. The horizontal edges in (a) result from the upstream partially closed power slits which are not influencing (b).

The arrival timing jitter between the X-ray and the PP laser on PAM was measured to be 20–30 fs RMS.

5.4. Pulsed magnet

In 2021, the HIBEF UC will install a 750 kJ capacitor bank with a peak current of 100 kA and pulsed magnets in different geometries: a horizontal bi-conical 60°–20° solenoid with peak fields of 60 T, and a split-coil (30 T) for diffraction experiments exploiting the full equatorial plane. Both coil systems integrate an eddy current shield in order to minimize stray fields and resulting vibrations due to interactions with the environment. The coils are cooled by liquid-nitrogen bath cryostats and the sample cryostat provides temperatures between 4 K and 600 K. The current design of the pulsed magnet setup represents a separate experimental platform optimized for peak field strengths and cryogenic temperatures. Thus, it cannot be used in conjunction with other drivers such as DACs or optical lasers. Furthermore, development of a phase retarder to control the polarization of the incident X-ray beam and of the polarization analyser for the scattered X-rays is currently ongoing.

6.1. Experimental hutch layout

The experiment hutch enclosure is constructed from up to 100 cm-thick heavy concrete walls, to anticipate the radiation and particles generated from the intense optical laser–matter interaction (e.g. using the ReLaX laser) and has been designed based on FLUKA simulations (Nakatsutsumi & Tschentscher, 2013; Battistoni et al., 2015). Transport of large equipment in and out of the hutch is possible through a 3 m-wide by 2.5 m-high sliding door.

The floor plan of the 4 m-high HED experiment hutch is shown in Fig. 13, and the X-ray beam path is 1400 mm above the hutch floor. The hutch is organized in two interaction areas (IAs): the X-rays enter IA1 by passing through a differential pumping section into the fixed interaction chamber (IC) 1 (see Section 6.2) and then proceed to IA2. All drivers except the pulsed magnet can be brought to the IC1 chamber. Furthermore, the ReLaX (Section 5.3.1) and DiPOLE (Section 5.3.2) laser beams are brought into the experiment hutch from the laboratory on the top floor through chicanes in the roof. On either side of the IC1 chamber are optical tables for optical laser diagnostics and optical sample diagnostics such as VISAR (Section 6.7.1).

Figure 13 Floor plan of HED experiment hutch with the positions of IC1 (right, rectangular), IC2 (center, round) and the AGIPD on the detector bench on the left. The XFEL beam enters from the right. The dark-gray areas indicate hutch infrastructure, while the orange areas mark access paths. Dimensions are given in millimetres.

The IA2 allows for various dedicated setups. Here, the IC2 chamber (Section 6.4) is permanently mounted on a rail system, which is embedded in the hutch floor, and can be brought into the beam, or parked by the wall. In the near future, IA2 will also host a goniometer for pulsed magnetic field experiments.

Downstream of IC1, rails run parallel to the X-ray beam path, carrying a 3 m-wide detector bench. It can be located at any position between the rear end of IC1 and the beam stop at the hutch wall. The bench is optimized to minimize vibrations and equipped with spectrometers and detectors including VAREX or AGIPD (see Sections 6.4.4 and 6.4.3).

The standards for vacuum in the experiment chambers require clean conditions at <10⁻⁴ mbar pressure (Schmidt & Dommach, 2015). This volume is decoupled from the ultra-high vacuum in the optics hutch and tunnels (∼10⁻⁹ mbar) by a differential pumping stage (DPS) which allows window-less X-ray operation. However, if the experiment requires ambient pressure, gate valves before IC1 and IC2 can be used to separate the chambers which are equipped with a 10 mm-diameter, 100 µm-thick diamond window with excellent X-ray transmission.

6.2. Interaction chamber 1

IC1 is a large multi-purpose chamber, manufactured by TOYAMA. All laser drivers, a manifold of sample geometries, spectrometers and other diagnostics can be arranged in vacuum around the X-ray beam at the TCC. The chamber body is made from an Al alloy to avoid long-duration nuclear activation during laser-plasma experiments which could interrupt user operation. Perpendicular to the X-ray path, large hinged doors allow easy access. The primary access doors open into a clean tent providing a flow of filtered air.

As the X-rays at European XFEL are horizontally polarized, scattering is preferably measured in the vertical plane where the scattered signal is not reduced by polarization effects. Therefore IC1 provides a vertical breadboard with motorized rails in the shape of circular arcs with the TCC in their centers (see Fig. 14). The arc radii are R = 306, 517 and 750 mm. Onto these, motorized carriages are mounted which can hold detectors and spectrometers of several kg weight. A central target mount and a horizontal breadboard are mechanically decoupled from each other and the vacuum chamber itself, and rest on separate granite supports. The dimensions of the horizontal breadboard are 2.3 m × 1.4 m, and the X-ray beam is (349 ± 1) mm above its surface. It provides M6 threaded holes in a 25 mm pattern. The IC1 walls are equipped with multiple feedthroughs with Japanese Industry Standards (JIS), ISO-K, and KF standards. On the roof of IC1, six turbomolecular pumps (HIPACE 800, Pfeiffer) with a pumping power of 790 l s⁻¹ (for N₂) pump the chamber through two large gate valves to <10⁻⁵ mbar.

Figure 14 (a) Cut through the schematic of the IC1 target chamber showing the vertical breadboard with circular rails. (b) Top view of the interior of IC1; the access doors are at the bottom. In red, a typical beam path for the ReLaX laser is shown, and the back line indicates a sample viewing system. The beam transport of the DiPOLE-100X high-energy laser in IC1 is flexible and customized configurations are currently evaluated.

6.2.1. Sample tower

In the center of IC1, an electrically and mechanically insulated sample tower consists of (from top to bottom): horizontal and vertical linear stages (Fast Sample Scanner), Hexapod (H-824, Physik Instrumente), 360° rotation stage (Goniometer 411, Huber Diffraktionstechnik), and a linear Y-axis (height) stage. It is possible to remove the Fast Sample Scanner to directly access the Hexapod. The scanner accommodates EUCALL (Appleby et al., 2017; see also Prencipe et al., 2017) standard sample holders and its travel ranges allows for 10 cm × 10 cm effective sample area available (see Fig. 15). Within these limits, the sample mount can be freely customized to the shape, thickness, structure and orientation as required. A description and specification for each stage is summarized in Table 5.

Table 5 Specifications of the sample tower Name Travel range Speed Repeatability Fast Sample Scanner horizontal 62.5 mm 0.1–20.0 mm s−1 2 µm Fast Sample Scanner vertical 57.5 mm 0.1–15.0 mm s−1 2 µm PI Hexapod horizontal ±22.5 mm 1 mm s−1 0.1–0.5 µm PI Hexapod vertical ±12.5 mm 1 mm s−1 0.1–0.5 µm PI Hexapod rotation (yaw, pitch) ±7.5° 11 mrad s−1 3 µrad PI Hexapod rotation (roll) ±12.5° 11 mrad s−1 3 µrad 360° rotation stage 360° N/A <10 µrad Height adjustment stage 150 mm N/A <0.3 µm

Figure 15 EUCALL standard frame design available at HED. The outer (blue) frame is unique to HED. The inner-frames (in gray/silver) can be customized for each experiment. This standard is employed at other beamlines at the EuXFEL, as well as other facilities such as ESRF and ELI beamlines.

6.2.5. X-ray spectrometers

Spectroscopy applications studying extreme states require vacuum conditions and sufficient flexibility for excitation methods and setup of the various technique-dependent spectrometers. In IC1, X-ray Emission Spectroscopy (XES) and Inelastic X-ray Scattering (IXS), both for meV and eV resolution, are provided. For in-vacuum use in IC1, we have designed highly efficient spectrometers (Preston et al., 2020) using cylindrical mosaic crystals in von Hámos geometry (von Hámos, 1934). Highly Annealed Pyrolytic Graphite (HAPG) crystals (Zastrau et al., 2013) with thicknesses of 40 µm or 100 µm or Highly Oriented Pyrolitic Graphite (HOPG) (Zastrau et al., 2012) with thickness 100 µm can be used, with radii of 50 mm or 80 mm. The spectrometer is designed to use either an ePix100 or Jungfrau detector. The HAPG crystals have demonstrated (Preston et al., 2020) to reach resolving powers of E/ΔE ≤ 2800 at photon energies between 5 and 10 keV. An example spectrum of Cr Kα is shown in Fig. 16. Fig. 17 shows these spectrometers mounted in IC1, together with three diced analyzers (see below).

Figure 16 Kα fluorescence of a 5 µm Cr foil irradiated by an 10 µm X-ray FEL spot for calibration purposes (black-dashed) with fit (red). The spectral broadening of the lines by the 80 mm radius-of-curvature and 40 µm-thick HAPG crystal is ∼2 eV. Reproduced from Preston et al. (2020).

Figure 17 3D schematics of up- and downstream HAPG spectrometers and three diced analyzers mounted on the curved rail system in IC1, leaving the horizontal breadboard free for laser optics and further instrumentation.

Furthermore, in conjunction with the aforementioned high-resolution Si(533) monochromator (see Section 4.3), several diced analyzer crystals can be coupled with a detector to provide 40 meV spectral resolution at 7495 eV. As shown in Fig. 18, this is sufficient to resolve inelastic X-ray scattering from phonons in solids, or ion-acoustic waves in plasmas (Wollenweber et al., 2021; Descamps et al., 2020).

Figure 18 The spectra of the Si(533)-monochromated beam scattered from PMMA (elastic, blue) and single crystal diamond (inelastic, red) resolved with a diced Si (533) analyzer crystal. For better comparison, the elastic signal is reduced by a factor of ten. For diamond, the peaks correspond to phonon creation and annihilation. The spectrum is reproduced from Wollenweber et al. (2021).

6.3. Small X-ray detectors

The HED instrument is offering compact and vacuum compatible X-ray detectors. All detectors are suitable for X-ray diffraction, and can be used in conjunction with the aforementioned spectrometers. They can be positioned inside IC1 using the vertical breadboard and motorized translation systems. In air, the detector bench in IA2 can be used to achieve larger sample–detector distances of up to 7 m for small-angle X-ray scatting (SAXS), radiography, or phase contrast imaging (PCI).

The detectors inside IC1 are the ePix100 (Blaj et al., 2016; Klačková et al., 2019), ePix100H hammerhead (Blaj et al., 2019), and the Jungfrau (Mozzanica et al., 2018). Their specifications are summarized in Table 6. The HED instrument currently offers two vacuum-compatible ePix100 modules to users, while two more modules with hammerhead sensors are foreseen. A dedicated air-box housing developed at European XFEL (Fig. 19) enables also the Jungfrau detector to be operated in vacuum. The Jungfrau features automatic gain switching of each pixel which allows detection of single photon events and high signal levels of up to 10000 12 keV photons in a single image (Redford et al., 2018, 2020). In total, four single Jungfrau modules are available and two modules can be combined into a larger detector with sensor size 2048 × 516 or 1024 × 1024 pixels with an inter-modular gap of 4.5 mm and 2.5 mm, respectively.

Figure 19 Model of the Jungfrau detector in an air-box, developed at the HED Instrument for in-vacuum operation.

6.4. Interaction chamber 2

IC2 [Fig. 20(a)] is optimized for diffraction experiments, exploiting the high photon energies and MHz time structure of the X-rays for the study of materials under extreme pressures, temperatures and strain rates. It hosts two experimental platforms: one for DAC experiments [Fig. 20(b)], and one for dynamic laser compression experiments using the DiPOLE 100-X laser (Fig. 21).

Figure 20 Interaction chamber IC2. (a) Vacuum chamber. (b) Platform for high-pressure research with diamond anvil cells.

Figure 21 Dynamic laser compression platform optimized for flexible experimental geometries. For the drive laser, this is realized through five individual laser entrance ports at angles of 22.5°, 45°, 67.5°, 90°, and 112.5° with respect to the incident X-ray beam, to which the DiPOLE beam transport is coupled via an external periscope system. The VISAR beam enters the chamber through a single port and covers an angular range from 202.5° to 310° via a pair of fixed and mobile mirrors inside the chamber. The Varex detector system can be rotated around the interaction point in steps of 7.5°.

The IC2 chamber has an outer diameter of 1360 mm and a height of 1520 mm. Further details are given by Liermann et al. (2021). The chamber is located in IA2 and can be moved between the operating and parking position on a rail system. The vacuum system allows for turnaround times below 30 minutes including venting, pumping and sample exchanges. IC2 can be coupled with either of two detector systems: the AGIPD 1M detector (Section 6.4.3), designed to resolve individual pulses at the minimum bunch spacing of the X-ray at 222 ns, and a twin configuration of two Varex flat-panel detectors (Section 6.4.4) for maximum gapless coverage at 10 Hz repetition rate in an EMP- and debris-resistant housing.

6.4.3. AGIPD detector

A dedicated 1 megapixel version of the Adaptive Gain Integrating Pixel Detector (AGIPD) (Allahgholi et al., 2019) will be integrated in order to perform diffraction experiments at the X-ray pulse repetition rate of 4.5 MHz within a pulse train [Fig. 22(a)]. The AGIPD features automatic gain switching covering a dynamic range from single photon sensitivity (at 12 keV) up to 10⁴ photons per pixel. Up to 352 frames per train (with adjustable bunch pattern) are acquired in analog pixel-based storage and read out at the train repetition rate of 10 Hz. While the initial version will be delivered with a 500 µm Si sensor, DESY FS-DS is currently developing an electron collecting high-Z version for increased efficiency at high X-ray energies. The 1 megapixel version consists of sixteen 128 × 512-pixel modules in an 8 × 2 arrangement. The system is integrated in an independent vacuum chamber, which is connected to IC2 through a DN 500 gate valve and bellow system, in order to keep the detector cooled and biased when the interaction chamber has to be vented for sample exchanges. Inside its chamber, the detector is mounted on a positioning unit, in order to extend the sensor area into the interaction chamber for maximum coverage of up to 2θ = 40° at sample–detector distance (SDD) = 150 mm corresponding to Q = 9 Å⁻¹.

Figure 22 (a) HIBEF AGIPD 1M detector and coverage as a function of X-ray energy. (b) Varex twin detector system and coverage as a function of X-ray energy for the downstream position.

6.5. Goniometer

A five-circle goniometer optimized for diffraction experiments in horizontal geometry with a load capacity of 300 kg is foreseen. It carries the magnet/sample cryostat assembly and can be reproducibly placed at IA2 by the use of kinematic mounts, alternatively to the interaction chamber 2. On the detector arm three different detector systems are planned: (1) an AGIPD module taking advantage of the pulse structure of the EuXFEL up to 4.5 MHz, (2) small pixel area detector module collecting diffraction data with higher angular resolution, and (3) analyser crystal for polarization-dependent scattering experiments.

6.6. Equipment operation under harsh conditions

Both the JUNGFRAU detectors in IC1 and the VAREX detector in IC2 are designed to operate together with the high-intensity (IC1) or high-energy laser (IC1 and IC2). The interaction of these lasers creates electromagnetic pulses (EMP) and secondary radiation. The detectors are operated in a vacuum-tight metal housing which acts as a Faraday cage. The JUNGFRAU detectors in IC1 show stabile operation during laser-solid interaction at intensities 10²⁰ W cm⁻². The more sensitive ePIX100 and AGIPD detectors are currently not compatible with high-intensity and high-energy laser experiments.

6.7. Optical diagnostics

In order to characterize the macroscopic state of dynamically compressed or excited matter, several optical diagnostics developed for the investigation of laser–matter interactions have been implemented. This is important for two reasons. First, the microscopic behavior of matter measured with X-rays can be related to macroscopic properties. Second, these diagnostics can measure the macroscopic evolution of the material over a large temporal and spatial scale, thus relating the point in time measurement of the X-rays with, for example, the compression history of a sample.

7.1. X-ray heating in DACs

Increasing the temperature in samples under pressure solely by exposing them to the MHz X-ray pulse train (Meza-Galvez et al., 2020) is an interesting alternative to the resistive or laser-heated DAC experiments (Spiekermann et al., 2020) because of the possibility to suppress chemical reactions and contamination of the sample from the diamond anvils. High-precision diffraction experiments IC2 coupled with simultaneous SOP provided the temperature evolution and verified sample stability. The DAC assembly proved to be robust in the XFEL beam, which will in future enable novel pulse-resolved diffraction experiments at extreme conditions including high strain rates using MHz detectors.

Recently, Hwang et al. (2021) observed the ultrafast synthesis of ɛ-Fe₃N_1+x in a DAC from Fe and N₂ under pressure using serial exposures of 17.8 keV pulses, using the IC2 DAC platform. When the sample at 5 GPa was irradiated by a pulse train separated by 443 ns (2.2 MHz), the estimated sample temperature at the delay time was above 1400 K, confirmed by in situ transformation of α- to γ-iron (Fig. 23).

Figure 23 The changes of X-ray diffraction patterns of iron and nitrogen during in situ chemical reaction by XFEL pump-and-probe. An Fe foil surrounded by N2 was pre-compressed to 5 GPa in a DAC. The percentages in run A indicate the transmission (fluence) of the XFEL. At 100% XFEL transmission, run B contains 20 consecutive pulses while run C has consecutive pulses over 11 s. For more details and figure credit, refer to Hwang et al. (2021).

7.2. Combined spectroscopy and diffraction experiments in DACs

Differently to IC2, the DAC setup in IC1 was used in a number of measurements that combined emission spectroscopy [at the Fe-emission lines (Lin et al., 2005)] and X-ray diffraction at 13 keV incident XFEL photon energy. The goal of the experiment was to study simultaneously the structure and electronic configuration of Fe-bearing compounds at extreme pressures and temperatures in situ. While under pressure, the sample was subjected to trains of several X-ray pulses which step-wise heated the sample in the DAC. During this temperature increase, the sample undergoes a spin cross-over (Cerantola et al., 2015), which was detected both in diffraction and emission signals.

7.3. Laser shock compression experiments on planetary materials

Geodynamic models of planetary interiors depend on the precise knowledge of the equation of state and the high-pressure phase diagram of materials such as SiO₂ and MgO. Previous studies demonstrated in shock compression experiments that these materials can transition from electrically insulating solids to conducting liquids at ultra-high pressures (Umemoto et al., 2006; Millot et al., 2015) which suggest, for instance, that planetary structure models need to include multiple layers of conductive fluids.

The use of the DiPOLE 100-X laser system will allow investigating matter at extreme conditions by laser-induced shock- and ramp-compression. It will be possible to investigate the model systems SiO₂ and MgO at pressures of up to several megabars at high or moderate temperatures with temporal pulse-shaping capabilities, which will consequently enable quasi-isentropic compression of material, reaching Hugoniot and off-Hugoniot high-pressure states.

The VISAR and SOP diagnostics will enable measurements of the pressure- and temperature evolution within the sample during shock transit, using a LiF or Al₂O₃ pressure window. Probing the materials during shock loading with the highly coherent and intense X-ray beam will permit the collection of time-resolved information about their respective density and crystal structures during compression.

7.4. Diagnosing relativistic laser plasmas

Small-angle X-ray scattering (SAXS) allows the detection of nanoscale density fluctuations. Typically, the SAXS signal from laser-excited plasmas is expected to be dominated by the free-electron distribution (Kluge et al., 2014); however, the fully tunable low energy-bandwidth XFEL pulses can be exploited for resonant SAXS (Kluge et al., 2016). Here, ionic scattering becomes visible when the incoming X-ray photon is in resonance with a bound–bound electronic transition. In this case, the scattering cross-section dramatically increases so that the signal of X-ray scattering from ions is silhouetted against the free-electron scattering background which allows the measurement of opacity and derived quantities with high spatial and temporal resolution.

In the harsh environment of high-intensity laser inter­actions, intense secondary radiation and high-energy particles are generated, and the SAXS signal may suffer a significant increase of noise. To mitigate the noise, a mosaic graphite crystal that works as a Bragg mirror for the SAXS signal between 8 and 9 keV is developed, which allows detecting the signal behind an appropriate shielding (Šmíd et al., 2020).

In addition, a solid target irradiated by a high-intensity laser pulse can become relativistically transparent, which then allows it to sustain an extremely strong laser-driven longitudinal electron current. The current generates a filament with a slowly varying Mega-Tesla level azimuthal magnetic field that has been shown to prompt efficient emission of multi-MeV photons in the form of a collimated beam required for multiple applications. At the HED instrument, these short-lived transient magnetic fields can be diagnosed via Faraday rotation (Wang et al., 2019).

7.5. Grazing-incidence X-ray scattering (GIXS) to track surface and subsurface density dynamics at nanometre resolution

The interaction between high-power, sub-ps lasers with metals or high-density plasmas occurs within the skin depth of the overcritical plasma, where the laser wave is evanescent. Therefore, the laser–plasma coupling relies on the details of the surface nano-structure within the skin layer, which amounts to a few tens of nm for solids. For a clear understanding of the complex physics involved in laser–matter coupling and subsequent energy transport, phase transition and surface expansion or ablation, it is crucial to visualize the surface and sub-surface density profile with nanometre and sub-ps resolution. X-rays become surface-sensitive in a grazing-incidence geometry, i.e. close to the critical angle for external total reflection which is typically below 1° for solids in the hard X-ray regime. In particular, grazing-incidence X-ray scattering (GIXS), which blocks the intense specular reflection and looks at the diffusely scattered 2D pattern, provides a wealth of information about the depth profile as well as the surface roughness and its correlation properties (Holy et al., 1993; Müller-Buschbaum, 2003; Roth, 2016). The first grazing-incidence X-ray scattering of a femtosecond XFEL beam combined with a high-intensity femtosecond laser has been successfully demonstrated at the SACLA XFEL in Japan (Randolph et al., 2020).

7.6. Probing the vacuum polarization

Vacuum in the presence of strong electromagnetic field contains pairs of short-lived quantum particles that can act as an electric dipole, which may in turn change properties of the background field, a process called vacuum polarization (Karbstein & Mosman, 2019). To detect vacuum polarization effects, the probing light, in this case the XFEL beam, has to be linearly polarized with a high degree of purity (Schlenvoigt et al., 2016). A specially designed highly optimized channel-cut polarizer and analyzer, each reflecting the beam six times inside the channel, has been shown to suppress residual light polarized in the orthogonal state to more than 11 orders of magnitude (Grabiger et al., 2020; Bernhardt et al., 2020). Such polarization purity is unprecedented for X-ray sources and opens up new opportunities for quantum optics and polarimetric experiments at XFELs.

7.7. Structure, electronic, and magnetic properties in pulsed high magnetic fields

One of the open questions in underdoped cuprate high-T_c superconductors is the nature and connection of the different charge density wave states with the upper critical field. To study the emergence of superconductivity from these phases, diffraction from the weak charge density wave peaks in very high magnetic fields is required (Gerber et al., 2015). Indeed, suppressing electronic order may provide a more general route to find new types of superconductors in various families of materials (Basov & Chubukov, 2011). The suppression of electronic order in high magnetic fields can also result in quantum criticality. Quantum critical matter in high magnetic fields may not only exhibit superconductivity but also electronic nematic phases (e.g. Fe-Pns) or so-called hidden orders, e.g. URu₂Si₂ (Mydosh & Oppeneer, 2011). In frustrated magnetic materials, diffraction allows the detection of broken structural symmetries accommodating a variety of magnetic phases, and magnetic scattering will make it possible to probe their order. Example systems where a magnetic field successively stabilizes a variety of novel exotic states (Ueda et al., 2017) are the rare-earth iridates of the A₂B₂O₇ pyrochlore structure. Here, resonant magnetic X-ray diffraction with polarization control and analysis could be used to probe the interplay between the rare earth and Ir, in order to understand the quantum metal–insulator transition.