1. Introduction

Spherically bent crystal analyzers are widely utilized in X-ray Raman/emission spectrometers (Schülke, 2007; Verbeni et al., 2009; Sahle et al., 2015, 2023; Huotari et al., 2017; Moretti Sala et al., 2018; Glatzel et al., 2021; Edwards et al., 2022). When the Rowland condition is fulfilled – namely, the sample (or the light source on it) and the detector are placed on a circle tangential to the crystal analyzer with a diameter equal to the bending radius of the crystal – photons emitted from the source are monochromated by the analyzer and then focused into a spot on the detector. Generally, for a spherically bent analyzer, a large Bragg angle reflection is exploited to achieve high energy resolution, high reflectivity and a large solid angle. However, as shown below, it becomes more difficult to maintain such advantages as the photon energy E increases. To maintain the large Bragg angle, it is necessary to utilize a very high index reflection, which generally has a small scattering form factor and thus a narrow Darwin width. A narrow Darwin width is essential to achieve an ultra-high resolution (1–10 meV). Nonetheless, the resolution generally required for X-ray Raman scattering (XRS) or X-ray emission spectroscopy (XES) is in the range 0.1–1 eV, and thus a too-small scattering form factor is disadvantageous in terms of the reflectivity or the integrated reflectivity. On the other hand, in the Laue geometry, X-rays transmit through the analyzer interior, resulting in low reflectivity or intensity of the reflected beam at E ≤ 10 keV due to absorption. Nevertheless, it exhibits performance suitable for XRS and XES at higher energies as discussed in our previous reports (Hiraoka et al., 2013, 2016). The author and co-workers have continuously studied the application of Laue analyzers since then (Nyrow et al., 2014; Hagiya et al., 2020; Hiraoka et al., 2023), and, currently, a spectrometer equipped with five Laue analyzers and five detectors are under commissioning. Although there is no question that the Bragg analyzer shows greater performance at E ≤ 10 keV (Cai et al., 2005; Gordon et al., 2007; Mao et al., 2010; Huotari et al., 2011; Willers et al., 2012; Sahle et al., 2013; Hiraoka et al., 2015; Georgiou et al., 2019, 2022), it may be still a question of whether the Laue analyzer indeed exhibits great performance at higher energies (Ravel et al., 2018; Jagodziński et al., 2019). In this article, we report on the (i) performance tests of the Bragg and Laue analyzers with the elastic scattering measurements on an SiO₂ glass sample, (ii) X-ray absorption spectroscopy (XAS) measurements in high-energy-resolution fluorescence-detection (HERFD) mode on 4d transition metals by the bent Laue analyzer, and (iii) a comparison between X-ray Raman features of the Li K-edge in LiF and O K-edge features in water measured by the two different analyzers.

2. Performance test with the elastic scattering in SiO₂ glass

To evaluate the performance of the two types of analyzers, the energy profile of elastic scattering was measured on an SiO₂ glass sample. The intensity and the width give the reflectivity and the instrumental resolution, respectively. The experiments were performed at the Taiwan inelastic X-ray scattering beamline (BL12XU) at SPring-8 (Cai et al., 2004). Synchrotron radiation emitted from an undulator light source was monochromated at E = 9.9–25.9 keV with an Si 111 double-crystal monochromator (DCM). The energy width of an Si 111 DCM is generally dE/E = 1.4 × 10⁻⁴ over E = 9.9–25.9 keV (LR setup). Another setup, where a high-resolution post monochromator was installed after the DCM, was also tried for a more critical test (HR setup). It is expected from analysis on a DuMond diagram that Si 220 channel-cut crystals in four-bounce mode give an energy width of dE/E = 0.3 × 10⁻⁴ over the current E range (Matsushita & Hashizume, 1983). The beam was focused to a 15 µm × 30 µm spot on the sample (V × H) by a Pt-coated Kirkpatrick–Baez mirror (Huang et al., 2008).

The energy profile of the elastic scattering on the SiO₂ glass sample (20 mm × 20 mm surface and 0.3 mm thickness) was measured by a spherically bent Si or Ge Bragg analyzer with a radius of 1 m or 2 m and a cylindrically bent Laue analyzer with a radius of 1.4 m. Note that the distance between the sample and the analyzer is close to the radius for the Bragg analyzer but it is significantly shorter for the Laue analyzer, 1.2 m.¹ The 〈111〉 orientation was utilized for the Bragg analyzers. Once the Bragg angle was fixed at 89.5°, the 555, 777, 888, 999 and 11 11 11 reflections were successively observed when E was scanned from 9.9–21.8 keV. For the Laue analyzer, the 〈110〉 orientation was utilized. When the Bragg angle was fixed at 30°, the 440, 660 and 880 reflections were observed at E = 12.8, 19.5 and 25.8 keV. Owing to practical limitations, to test the Laue analyzer the undulator gap was set to generate the first harmonics at E = 6.53 keV. The strong beam was available at E = 19.6 keV whereas there were only the weak beams at E = 12.8 keV and 25.8 keV. Nonetheless, this is not an issue for the test as long as the photon flux is correctly monitored.

Table 1 indicates the parameters for the analyzers used in the test. The Si or Ge Bragg analyzers are glued onto the quartz glass substrates with a 1 m- or 2 m-radius curved surface, while the Laue analyzer has no substrate. The base of the triangular wafer was clamped by aluminium blocks while the apex was displaced by the remote actuator, facilitating a continuous change of the radius. The detector for the Bragg analyzers was a photon-counting, Si diode point detector (5 mm diameter and 0.5 mm thickness) while the detector for the Laue analyzer was an NaI scintillation counter (50 mm × 50 mm surface and 3 mm thickness). The scattering angle was adjusted so that the same momentum Q was probed while scanning E from 9.9 keV to 25.8 keV. The solid angle for photon acceptance for the Bragg analyzers was determined by an aperture of the mask in front of the analyzers. Circular masks of 75 mm- and 85 mm-diameter openings was used for 1 m- and 2 m-radius analyzers, respectively, corresponding to acceptance solid angles of 4.4 × 10⁻⁴ sterad and 1.4 × 10⁻⁴ sterad. On the other hand, the acceptance solid angle for the Laue analyzers was defined by a rectangular mask between the sample and the analyzer. The mask was 0.75 m from the sample and the opening was 10 mm × 20 mm (V × H), giving 2.8 × 10⁻⁵ sterad. The aperture could be opened, but the energy resolution would substantially deteriorate. Therefore, we kept it at 10 mm × 20 mm throughout the test. It remains an issue to be addressed in future of how to make the aperture larger while maintaining the energy resolution at 1–2 eV.

Fig. 1(a) shows the energy profiles of the elastic scattering measured by the 2 m-radius Si Bragg analyzer and Fig. 1(b) shows those by the 1.4 m Si Laue analyzer. The notation LR stands for measurements taken with a beam from the Si 111 DCM. The Si 111 reflection has a bandpass mostly larger than those of the analyzers. The HR notation is for measurements taken with the Si 220 four-bounce high-resolution monochromator, which generally has a bandpass that is narrower than those of the analyzers. The reflectivity ρ here is defined as (see Appendix A)

where I is the integrated intensity of the elastic scattering, I₀ is the incoming photon flux, τ is the transmittance through the sample and the air/helium path, ε is the quantum efficiency of the detector (taking the transmittance through the Be or Al windows into consideration), and σ is the solid angle for the photon acceptance as already discussed above. I and I₀ are observable whereas τ and ε can be calculated using the absorption coefficients. Assuming a perfect in-plane polarization of the incoming beam, the polarization factor p is given as (1 + cos2Θ)/2, where Θ is the scattering angle. The energy dependence for each parameter is shown in Fig. 2. The constant c is a normalization factor.

Figure 1 Energy profiles of the elastic scattering on SiO2 glass measured by the (a) 2 m Si Bragg analyzer and (b) 1.4 m Laue analyzer. The insets indicate the experimental geometries.

Figure 2 I is the integrated intensity of the elastic scattering, I0 is the incoming photon flux, τ is the transmittance through the sample and the air/helium path, ε is the quantum efficiency of the detector, and p is the polarization factor. Transmittance through the Be or Al windows is included in ε. (a) Bragg analyzer. (b) Laue analyzer. (c) S(Q) of SiO2 glass measured by the Laue analyzer with 27 keV photons (0.17 Å−1 resolution in Q-space). The reflectivity tests were conducted at Q = 2.62 Å−1.

Fig. 3(a) displays the reflectivity ρ as a function of photon energy. Here, c is determined such that the reflectivity of the 2 m-radius Si 555 Bragg analyzer is 1. Similar experiments were conducted with a 1 m-radius Si〈111〉 Bragg analyzer (triangles in Fig. 3) and a 2 m-radius Ge〈111〉 Bragg analyzer (diamonds). The reflectivity of the Laue analyzer in E = 10–30 keV is excellent. The reflectivity of the Bragg analyzers decrease as E increases. The 888 reflections appear somewhat stronger than the others as this is an even-number reflection, which generally has larger scattering structure factors. The reflectivity of the Ge analyzer is lower than that of Si because Ge has a larger absorption coefficient. The Ge K-edge is around 11 keV. Therefore, in the energy range above this, the reflectivity is particularly low.

Figure 3 Energy dependence of the (a) reflectivity ρ and (b)–(c) energy resolutions ΔE. The circles and triangles represent the 2 m- and 1 m-radius Si Bragg analyzers, respectively, and the diamonds represent the Ge Bragg analyzer. The squares represent the 1.4 m-radius Si Laue analyzer. The scale is normalized such that ρ = 1 for the 2 m Si 555 reflection. LR stands for measurements taken with a beam from the Si 111 DCM. The Si 111 reflection has a bandpass mostly broader than those of the analyzers. HR is for measurements taken with the Si 220 four-bounce high-resolution monochromator, which generally has a bandpass narrower than those of the analyzers. The monochromator contributions ΔEMON to the resolution are shown by broken lines in (b) and (c). Note that ΔEMON and the analyzer contribution ΔEANA cannot be linearly summed for most cases: for example, ΔETOT2 = ΔEMON2 + ΔEANA2 if they have Gaussian shapes.

Regarding the energy resolution, the Ge analyzer shows the narrowest width while the Bragg Si shows the widest. The Laue analyzer is between these two. Based on the lamellar model (Erola et al., 1990), those behaviors can be understood as follows. In a bent crystal, the lattice parameter and the incident angle to the diffraction plane vary as a function of the position from the front surface along the thickness directions (see inset in Fig. 3) (Suortti et al., 1986a). This variation is why bent crystals have a large bandwidth and show a larger (integrated) reflectivity (Suortti et al., 1986a,b; Pattison et al., 1986). Nonetheless, Ge has a stronger absorption, so that only diffraction planes near the front surface contribute to the reflections. Therefore, the Ge analyzer shows the narrowest width and the lowest intensity. In a similar way, it can be understood why the 1 m-radius Si Bragg analyzers has a higher (integrated) reflectivity than that of the 2 m-radius ones. This is because of the larger difference between the Bragg angles near the front surface (θ₁ in Fig. 3 inset) and those in the interior (θ₂). Note that the reflectivity in Fig. 3(a) is already corrected for the difference of the solid angles and thus the difference in the reflectivity solely arises from the increase (or decrease) of the bandwidth in the energy. In the Laue analyzer, the effects attributed to the variation in the lattice parameter and the rotation of the diffraction plane can be compensated (Erola et al., 1990). The degree of compensation can be controlled by the magnitude of the asymmetric cut. This fact was already discussed in a previous report (Hiraoka et al., 2013). All of the Laue crystals used in this experiment have a 1° asymmetric cut.

As mentioned above, Laue analyzers currently perform well when only a limited area is used with a mask. Fig. 4 shows the elastic line profile as a function of the aperture size. As the aperture size increases, the line profile broadens and a tail becomes more prominent, indicating a deterioration in the resolving power. Currently, a 10–20 mm × 20 mm (V × H) aperture is commonly used. A horizontal opening also deteriorates the resolution, but its effect is less significant compared with the vertical (not shown). Therefore, using a rectangular crystal along with a larger surface detector may increase the active area and enhance the intensity. Nonetheless, in a preliminary test conducted earlier, a resolution better than 2 eV was not achieved with a rectangular crystal. The exact reason for this remains unknown; it could be due to an inappropriate design of the crystal bender or poor quality of the crystal itself. Since then, triangular crystals have been used.

Figure 4 Energy profile of the elastic line measured by the Laue analyzer on SiO2 glass as a function of aperture size (a), and analyzer layout (b).

3. HERFD-XAS measurements on 4d transition metals with Laue analyzers

HERFD-XAS draws much attention from scientists studying catalysts because it can be a powerful tool to find the active site and to clarify the reaction process (Hung et al., 2018; Guo et al., 2020; Bai et al., 2021; Feng et al., 2024; Matsuyama et al., 2024). Conventional XAS, whether in transmission or fluorescence mode, suffers from the considerable broadening effects due to the core-hole lifetime, unless the core is shallow (E ≤ 1 keV). In HERFD-XAS, one of several fluorescence lines emitted from the sample is focused, and the incident photon energy is scanned across the absorption edge by recording a peak (not integrated) intensity of the fluorescence (Hämäläinen et al., 1991; Bauer, 2014). This suppresses the lifetime broadening, allowing fine structures to be easily identified. Currently, HERFD-XAS is often performed on the K-edge in 3d transition metal elements or L-edges in the 5d elements because they have emission lines around 10 keV and thus widely used Bragg analyzers work well at this energy. On the other hand, although the 4d transition metals include many important elements for catalysis or other energy materials, such as Mo, Rh, Pd and Ag, there are far fewer reports for HERFD-XAS on these elements (Lima et al., 2013). They have emission lines around 20 keV and it is more difficult to achieve a sufficient intensity and resolution at this energy by Bragg analyzers. The Laue analyzer has a great advantage for HERFD-XAS studies on 4d transition metals.

Fig. 5(a) shows the K-edge HERFD-XAS spectra of Zr, Nb, Mo, Ru, Pd and Ag thin films (∼20 µm) measured by the Si 660 Laue analyzer. They are compared with the total fluorescence yield (TFY) XAS spectra measured by an Si PIN diode simultaneously. The incident photon energy was scanned using the Si 220 four-bounce HRM. During the scans, the peak intensities of the Kβ₁ lines were monitored for Zr and Nb foils whereas the Kα₁ lines were monitored for Ru, Pd and Ag foils. For Mo, both lines were monitored to ensure consistency. The overall energy resolution of the instrumentation was 1–2 eV. The energy resolutions evaluated at each edge are summarized in Table 2.

Figure 5 (a) HERFD- and TFY-XAS spectra on 4d transition metals, and (b) partial densities of states calculated by band theory.

The lifetime of the 1s core hole in 4d transition metals is substantially short, and thus the broadening effect is significant. The effect is larger as the atomic number increases. For Pd and Ag, it can be as large as 10 eV. Because of this, in TFY-XAS it is difficult to find the difference among late 4d elements in particular. In contrast, in HERFD-XAS, such a broadening is largely suppressed, and clear differences are readily recognized. The features in HERFD-XAS agree well with the distribution of the partial density of states of p-symmetry (p-DOS) calculated by band theory.² Generally, 4d transition metals have larger spin–orbit couplings than 3d transition metals and, therefore, their spectra comprise some d-DOS in valence bands. However, it is clear from comparing the HERFD-XAS spectra and the d-DOS in Fig. 5 (note the p-DOS is multiplied by a factor of 20) that such a contribution would not be major. This conclusion agrees with the past report (Lima et al., 2013).

4. Comparison of Raman features measured by Bragg and Laue multiple analyzer spectrometers

When performing XRS experiments, an interesting question is whether the Bragg spectrometers operating at E ≃ 10 keV or the Laue spectrometer at E ≃ 20 keV will produce better quality data in terms of the intensity, energy resolution and other aspects. The answer depends on the experimental conditions, such as the light source, the optics (e.g. monochromator and mirrors), the number and size of the analyzers, and the type of detector used. For an example, we compare XRS spectra measured in BL12XU, SPring-8. Here, beams of similar intensities and the same focal sizes are available at E = 10 keV and 20 keV (2 × 10¹³ photons s⁻¹ versus 1 × 10¹³ photons s⁻¹ in a 15 µm × 30 µm focus). Furthermore, a multiple-analyzer spectrometer equipped with 9 or 15 Si Bragg analyzers with a 2 m radius and a spectrometer with 5 Laue analyzers with a 1.4 m radius are available.

The advantages of the Bragg spectrometer are as follows. (1) In principle, the reflections of all analyzers can focus onto a point. Therefore, a high density of photons is available in a small area on the detector. This is advantageous for obtaining a high signal-to-background ratio. (2) The Bragg spectrometer is suitable for high-energy-resolution experiments. The influence of the angular variation Δθ on the energy variation ΔE is given by ΔE/E = Δθ/tanθ_B. θ_B closer to 90° produces a higher resolution. (3) For a similar reason, the spectrum is insensitive to the beam fluctuation. Assuming θ_B = 89°, a 1 mm beam shift only leads to an energy shift as small as 0.1 eV or less.

The advantages of the Laue spectrometer are as follows. (1) The degree of freedom for the sample environment is high because the detector is very far from the sample, providing a large available space. In addition, sufficient intensity can be obtained even with a small aperture for the scattered photons owing to the high reflectivity per unit solid angle. Also, high Q is achievable using high-energy photons even within a limited 2θ range. (2) The transmission geometry is straightforward since high-energy photons have high penetration power. Critical alignment of the sample is not required unlike in the reflection geometry, and a poor surface does not reduce the scattering intensity. (3) The scan range for the scattered photons is wide as a small motion of θ_B corresponds to a large ΔE. Even a scan over several kiloelectronvolts is possible (Hiraoka et al., 2020, 2023; Yang et al., 2020; Hagiya et al., 2020). The Bragg analyzers generally operating at very large θ_B provide a scan range of only several electronvolts (when θ_B ≃ 85°) or several tens of electronvolts (θ_B ≃ 80°), and thus the incident photon energy is usually scanned instead of the scattered photon energy in XRS. In addition, access to a larger Q range may be advantageous for studies of non-dipolar transitions on the excitation from deep core levels (Yavaş et al., 2019; Leedahl et al., 2019).

Fig. 6(a) shows the Li K-edge feature in LiF measured by the Bragg spectrometer with nine analyzers and by the Laue spectrometers with five analyzers. The scattering angles 2θ = 16° and 8° correspond to the same momentum Q = 1.41 Å⁻¹ at E = 10 keV and 20 keV, respectively. Note that Q is the same for the central analyzer but differs slightly for the others. The energy resolutions determined with the elastic scattering are 1.4 eV for both.

Figure 6 Lithium K-edge in LiF (a) and oxygen K-edge in H2O (b) Raman features measured by the nine Bragg analyzers (c, left) and the five Laue analyzers (c, right).

In the experiment at 10 keV the beam from the Si 111 DCM was used directly without the HRM, while in the experiment at 20 keV the Si 220 HRM was used after the DCM. The beam intensity in the latter experiment was weaker by a factor of 10 (2 from the light source property and 5 from the HRM). Furthermore, the number of the analyzers (×5/9) and the solid angles for each (×1/4) were smaller in the latter experiment. Nonetheless, the count rates in two experiments are similar. One reason is the larger transmission through the sample of 20 keV photons (×3–4) but the major reason is the high reflectivity of the Laue analyzers.

The Laue spectrometer may be advantageous for studies on energy materials such as batteries and catalysts as these samples are often subject to radiation effects. It would be significant if one could obtain spectra of similar quality with a small number of photons. Furthermore, an absorption coefficient decreases as the photon energy increases. At 10 keV and 20 keV, it differs by a factor of 6–8. Assuming that the dose is proportional to the absorption coefficient × number of photons × photon energy, the dose at 20 keV amounts to only several percent of that at 10 keV.

Fig. 6(b) shows the oxygen K-edge features in H₂O in a capillary with a 2 mm or 5 mm diameter. For both experiments, the scattering angle was 30°, which corresponds to 2.62 Å⁻¹ (1.39 a.u.) for E = 10 keV and 5.24 Å⁻¹ (2.78 a.u.) for 20 keV. If the radius 〈r〉 of the oxygen 1s orbital is assumed to be a_B/Z = 0.125 a.u., where a_B is the Bohr radius (1 a.u. = 0.529 Å⁻¹) and Z (= 8) is the nuclear charge, one obtains Q〈r〉 = 0.174 and 0.348, indicating the dipole transition dominates the XRS spectra for both. The count rate at the maximum near E − E₀ = 535 eV was 300 counts s⁻¹ at E = 10 keV and 280 counts s⁻¹ at 20 keV.³ Although it is difficult to say which spectrometer is superior because the optimum conditions are different, it is likely that similar-quality spectra can be obtained for both once the experimental conditions are optimized.

5. Conclusions

A performance test of spherically bent Bragg analyzers and cylindrically bent Laue analyzers has been conducted. The Bragg analyzer displays an excellent performance at E ≤ 10 keV, though the performance gradually deteriorates at higher energies. The Laue analyzer exhibits a superior performance at a high-energy region, indicating that the two types of spectrometers operate in a complementary way. Regarding XES, the Bragg analyzer is generally a better option for measuring the K emission lines from the 3d transition metals or the L emission lines from the 5d metals as they are in the E ≤ 10 keV range. The Laue analyzers have an advantage in the measurement of K emission lines from 4d metals, which exist around 20 keV. Concerning the 4f rare-earth elements, the L emission lines are often measured, but the K emission lines have been scarcely studied so far. This vast field remains largely unexplored. XES studies of K lines from early rare-earth metals such as La and Ce are among the future targets, which require a spectrometer operating at 30–40 keV. High transmission power of high-energy photons provides us with significant flexibility on the sample environment, such as high temperature, high pressure and in situ/operando cells.

As for XRS, the spectrometer equipped with nine 2 m-radius Bragg analyzers (operating at E ≃ 10 keV) and the spectrometer with five 1.4 m-radius Laue analyzers (at ∼20 keV) show similar performances. They can be switched depending on the purpose. For example, the Bragg analyzers are advantageous if an energy resolution of ΔE < 1 eV is required. They are also advantageous for very low count rate (several counts s⁻¹) experiments. On the other hand, the Laue analyzers are advantageous for the experiments requiring a high-penetration power and/or a large space around the sample. The current challenge for this analyzer is that only a small portion of the surface can be used to maintain the 1–2 eV resolution. Developing higher-precision benders and using rectangular crystals instead of triangular ones are required to overcome this issue. XRS studies on light-element ingredients in metals, such as carbon in steel, will be an interesting challenge. This would also require high-energy photons.