1. Introduction

Most industrial catalysts are used in the form of supported-metal catalysts. The role of the support is not only to disperse the active sites but also to modify the catalytic properties through so-called `metal–support interactions'. Although a number of concepts have been proposed to explain the metal–support interaction, lack of accurate knowledge about the interface structures and the bonding features between active metal sites and support surfaces inhibits a full understanding of the essence of the metal–support interaction.

Extended X-ray absorption fine structure (EXAFS) spectroscopy is one of the most powerful techniques currently used to study the structure of supported catalysts (Koningsberger & Prins, 1988; Iwasawa, 1996). In order to determine the interface structure in a supported catalyst, EXAFS has been applied to model catalysts in which small metal particles are deposited on powder oxides (van Zon et al., 1984; Martens et al., 1988; Koningsberger & Gates, 1992; Asakura et al., 1985; Koningsberger et al., 1996). However, careful interpretation and analysis are required to elucidate the interface structures because the results derived from the usual EXAFS are averaged in all directions and the contribution from the interface structure is often weaker than that from the metal–metal interaction in the metal particles.

EXAFS has a polarization dependence expressed as

where χ(k), θ_i and χ_i(k) are an EXAFS oscillation, an angle between the ith bond and the polarization vector of the incident X-ray, and an EXAFS oscillation accompanying the ith bond, respectively. Hence, equation (1) indicates that if one can use a flat substrate with active metal species deposited thereon and set the sample surface parallel to the electric polarization vector, one can obtain the interface structure selectively.

In order to investigate the structure of the metal species dispersed on the flat substrate, we have developed polarization-dependent total-reflection fluorescence X-ray absorption fine structure (PTRF-XAFS) spectroscopy (Asakura et al., 1993, 2000; Shirai & Iwasawa, 1996). The total-reflection fluorescence mode is necessary to obtain EXAFS of the surface species when the coverage of the surface species is less than one monolayer (Heald et al., 1984, 1988; Chen & Heald, 1993). We have applied the method to Co oxide on α-Al₂O₃ (0001), Cu oxide on α-quartz (0001), Pt₄ clusters on α-Al₂O₃ (0001), and Mo oxide on rutile TiO₂ (110) (Shirai et al., 1992; Shirai, Asakura & Iwasawa, 1994; Shirai, Inoue et al., 1994; Asakura et al., 1997; Chun et al., 1998). We have found that Pt deposited on α-Al₂O₃ (0001) has a one-atomic-layer structure with Pt—O(Al) = 0.220 nm (Asakura et al., 1997). In the Mo oxide on TiO₂ (110), a dimer structure is formed with an Mo—Mo bond perpendicular to the (001) direction and Mo—O(Ti) and Mo—Ti distances of 0.220 and 0.295 nm, respectively (Chun et al., 1998). We have also developed an in situ PTRF-XAFS chamber suitable for catalyst samples investigated under reaction conditions (Shirai et al., 1995). However, it was difficult to install a heavy multi-element solid-state detector (SSD) for the fluorescence detection or an LEED (low-energy electron diffraction)–AES (Auger electron spectroscopy) instrument for surface characterization, because the position and orientation of the whole chamber needed to be adjusted to obtain the total-reflection conditions.

In this paper, we report the design and the performance of a newly built in situ system for PTRF-XAFS measurements. The system had to realise the following concepts.

2. In situ PTRF-XAFS system

To satisfy the above conditions (iv) and (v) at the same time, we constructed two separate ultra-high-vacuum (UHV) chambers, a sample-preparation chamber and a PTRF-XAFS measurement chamber, between which samples are transferred with a transfer chamber.

Fig. 1 illustrates the measurement chamber, the dimensions of which are 400 (width) × 400 (length) × 600 (height) mm and the base pressure of which is 10⁻¹⁰ torr (1 torr = 133.32 Pa). Reaction gases can be introduced through two leak valves and gas-phase analysis can be carried out by a quadrupole mass spectrometer (Q-mass; Balzers Co., Prisma). Incident and reflected X-rays pass through two Be windows (thickness 200 µm, diameter 14 mm, purity 99.8%). The beam size of the incident X-rays can be adjusted by selecting a series of Ta pinhole slits in front of the I₀ ionization chamber.

Figure 1 The in situ polarization-dependent total-reflection fluorescence (PTRF) measurement chamber with the sample-transfer chamber.

A multi-element SSD can be placed outside the chamber and the fluorescence signal is extracted through Be windows attached to the UHV flange. The positions of the Be windows are in line with those of the SSD windows in order to obtain maximum efficiency. The use of a multi-element SSD increases the solid angle and the maximum counting rates, as reported by Oyanagi & Nomura (Oyanagi et al., 1998; Nomura, 1998). Moreover, the SSD can eliminate residual elastic scattering and fluorescence of the substrate and coexisting elements in order to increase the signal-to-background ratio. In the PTRF-XAFS measurement of a single-crystal substrate, diffracted beams from the substrate produce a discontinuity in the spectra at certain energies. Because the directionality of the diffracted beam is sharp, the diffraction line can be eliminated by an adequate adjustment of the detector position (Chun et al., 1996). In the multi-element detection system, the diffracted beam can be easily removed by omitting the data of a few detector elements that suffer from the diffraction line, as shown in Fig. 2.

Figure 2 The fluorescence signals from each element of a 19-element solid-state detector (SSD). The sample is Cu/TiO2 (110).

The sample can be heated up to 600 K by resistive heating of W wire mounted in the sample holder. A ceramics block thermally and electrically isolates a goniometer from the sample holder.

To achieve total-reflection conditions precisely, we have used a UHV-compatible six-axis goniometer, as shown in Fig. 3. The goniometer is made of aluminium in order to lessen the weight load on the stepping motors. The rotation centre of the goniometer is fixed at that of the sample surface. Three (θ, φ and χ) rotation axes are driven by bake-proof vacuum stepping motors (Oriental Motors Co. UPX535M), while x, y and z motions are introduced from outside the chamber using usual stepping motors (Oriental Motors Co. UPD533HGI-NA, UPK564A-TG20). The range and precision for each axis are listed in Table 1.

Figure 3 The high-precision UHV-compatible six-axis goniometer and its configuration for measurements against three different polarization directions: (a) s-polarization (E || surface), (b) p-polarization (E ⊥ surface) and (c) the second s-polarization but perpendicular to the direction of (a).

Fig. 4 shows the X-ray reflectivity of the TiO₂ (110) surface at an energy of 9.3 keV. The critical angle was 3 mrad. The angle and the position could be reproduced even after a wide range of rotations and movements at room temperature. However, there was a small shift in the angle datum point when the sample was heated at elevated temperatures. The broken line in Fig. 4 represents the X-ray reflectivity of the same sample after heating at 473 K and cooling to room temperature in hydrogen atmosphere. The shift of the datum point was only 0.5 mrad. Therefore, one has to readjust the total-reflection conditions when the sample has been heated at a different temperature.

Figure 4 X-ray reflectivity of the TiO2 (110) single crystal. The solid line and the broken line correspond to the reflectivities before and after heating the sample at 473 K, respectively.

Fig. 3 shows the setup of the goniometer for three different sample configurations, i.e. the electric vector perpendicular to the surface (p-polarization) and those parallel to the surface (s-polarization). If the surface symmetry is less than threefold, two directions parallel to the surface can be distinguished. For example, rutile TiO₂ (110) has different structures between the [001] and [10] directions (Chun et al., 1998).

Fig. 5 shows a perspective view of the preparation chamber. The UHV chamber [350 (width) × 350 (length) × 400 (height) mm] can be equipped with Q-Mass, LEED, AES and XPS (X-ray photoelectron spectroscopy) instruments. The base pressure is 10⁻¹⁰ torr. The substrate crystal can be cleaned by repeated Ar-ion sputtering and annealing cycles in the preparation chamber. A large crystal (more than 2 cm long) is required in order to increase the radiation area for grazing-incidence conditions. The sample can be completely covered with the mug-shaped heating module and annealed homogeneously up to 1000 K.

Figure 5 The sample-preparation chamber and the sample-transfer chamber.

The prepared samples are then transferred to the measurement chamber using a small transfer chamber, which is also operated under UHV conditions. A non-evaporable getter pump is installed to maintain the high vacuum during the transfer of the sample from the preparation chamber to the measurement chamber in a beamline. The transfer chamber can contain two samples at the same time and thus the transfer chamber may be used as a `parking lot' for the samples.

3. In situ PTRF-XAFS measurement of Cu particles on TiO₂ (110) derived from Cu(DPM)₂ as a precursor under temperature-programmed reduction

Cu/TiO₂ shows high activity in methanol synthesis by CO₂ hydrogenation and photocatalytic reduction of N₂O at room temperature. As a model of the Cu/TiO₂ catalyst, we deposited a Cu species on a TiO₂ (110) single crystal. We used Cu(DPM)₂ (DPM = 2,2,6,6-tetramethyl-3,5-heptanedione) as the precursor for the Cu species, which can be easily reduced at low temperature under H₂ atmosphere (Sekine et al., 1992). Cu species were deposited on the TiO₂ (110) by dropwise addition of a diethyl ether solution of Cu(DPM)₂ under Ar flow. The remaining solvent was removed by evacuation for 24 h. The samples were then transferred to the measurement chamber.

Temperature-programmed reduction (TPR) was carried out in the measurement chamber at a rate of 8 K min⁻¹ under 2 torr H₂. PTRF-XAFS spectra were measured at BL12C of the Photon Factory in the Institute of Material Structure Science, High Energy Accelerator Research Organization (KEK-PF) (Proposal No. 98 G305). The synchrotron radiation was monochromated by a Si (111) double-crystal monochromator. The storage ring was operated at 2.5 GeV and 200–400 mA. Cu K-edge EXAFS spectra were recorded in the range 8660–9500 eV at room temperature. The X-ray beam size was reduced to 0.4 mm in diameter in order to decrease unnecessary irradiation.

Cu K-edge XAFS measurements were carried out in three different directions of the electric vector of the incident X-rays, i.e. parallel to the [10], [001] and [110] axes of TiO₂ (110). Fig. 6 shows the PTRF-XANES spectra parallel to the [001] direction during the TPR process. By increasing the reduction temperature, we observed that the pre-edge shoulder in the XANES spectra gradually increased up to 363 K. Fig. 7 shows the background-subtracted PTRF-EXAFS spectra of the sample treated at 363 K. χ(k) along the [001] axes showed different features compared with the behaviour in other directions. The detailed analysis of the EXAFS data will be discussed in another paper (Tanizawa et al., 2001) but the EXAFS data clearly indicate the presence of anisotropic structure caused by the preferential formation of Cu—Cu bonds along the [001] direction of the TiO₂(110) support.

Figure 6 XANES spectra along [001] during the temperature-programmed reduction (TPR) process. RT = room temperature.

Figure 7 EXAFS oscillations for Cu/TiO2 reduced at 363 K: (a) E || [10], (b) E || [001], and (c) E || [110].

4. Conclusion

PTRF-XAFS has become a practical tool for the determination of the structure of the dispersed species on model single-crystal surfaces and enables us to start systematic investigations of metal–support interface structures.