1. Introduction

Metal film deposition techniques are critical for their applications in microelectronics, photonics, catalysis, biochemical sensors and so forth (Fukumi et al., 1994; Loo et al., 2005; Chah et al., 2005; Haruta, 1989; Ma et al., 2000). Radiolysis is of significant interest, since it is easier to carry out at room temperature under atmospheric conditions. More importantly, it is independent of the preliminary use of reducing agents, leading to the production of highly pure metals with less contamination (Bharti et al., 2016; Wang et al., 2007). Nowadays synchrotron radiation X-ray radiolysis (Yamaguchi et al., 2016, 2017; Oyanagi et al., 2014; Bharti et al., 2017; Jingyuan et al., 2013; Matsumoto et al., 2015) has become a convenient route for obtaining metal nanostructures with desired sizes, shapes and properties. Bharti et al. (2016) explored monochromatic X-ray induced silver nanoparticles for a photovoltaic cell. Ma et al. (2000) successfully achieved the formation of a metallic pattern/structure on a substrate, which could help in the development of low-cost test photomasks and microelectronics. Synchrotron radiation induced metal deposition has become a hot topic in the engineering fields.

However, the mechanism of X-ray stimulated processes is still unclear because it is a rapid dynamic chemical process with great heterogeneity in the liquid bulk phase. Early literature suspected that water molecules in solution could be ionized or excited under high-energy X-ray irradiation (Ma et al., 2008; Gachard et al., 1998; Abedini et al., 2013). Heterogeneous charge distribution might exist in the system; the X-ray illuminated volume should be charged more positively than the non-illuminated volume. Complexes such as AuCl₄⁻ may be driven towards the illuminated area, whereas the activated solvent can supply reducing radicals to neighbouring Au ions and contribute to the formation of zero-valence Au (Wang et al., 2007). In situ time-resolved X-ray absorption spectroscopy (XAS) was employed to track the reduction of Au ions in aqueous solution in the presence of supporting materials (Ohkubo et al., 2014). This demonstrated that the deposition process depended on the relationship of surface charges between metal ions and supporting materials. Nevertheless, these studies were not available for the spatial chemical speciation distribution which is crucial to our understanding of X-ray stimulated processes.

Micro-X-ray fluorescence (XRF) and XAS are powerful tools for spatially resolved structure analysis via sample mapping in the micrometre regime and have a large variety of fields of application such as environmental sciences, geology, life sciences and archeology. Importantly, the use of confocal X-ray optics, especially capillary optics (Kanngießer et al., 2003), provides a feasible route to analyze geological and cultural heritage samples with depth-resolved chemical speciation of elements (Vekemans et al., 2004; Lühl et al., 2014; Kanngießer et al., 2012; Denecke et al., 2009). In confocal mode, a probing volume is created by the overlapped foci of two optics; the first one is placed in an excitation channel and the second in a detection channel. Confocal detection restricts the probed fraction of the sample to an ellipsoidal volume allowing non-destructive depth-resolved measurements. Confocal micro-X-ray fluorescence is nowadays applied for the measurements of ion distribution near the surface of an electrode, revealing the liquid mass transfer in electrolytic tanks in situ (Song et al., 2014). Confocal micro-XAS was also introduced to probe the oxidation states at the cathode/electrolyte interface of an Li ion battery in operando (Menzel et al., 2013). This gives important impetus for the developmet of spatially resolved analysis in order to understand the photochemical processes induced by X-ray radiolysis.

In this study, confocal micro-XAS was set up at Beijing Synchrotron Radiation Facility (BSRF). Au ions were irradiated with synchrotron monochromatic X-rays; while confocal micro-XRF monitored the metal ion distribution, confocal micro-XAS examined the oxidation state of metal ions in aqueous solution. By combining the results from confocal X-ray spectroscopy with that from X-ray contrast imaging, the mechanism of synchrotron radiation induced Au deposition was proposed, aiding our understanding of the X-ray stimulated process.

2. Experimental instrumentation

The experiments were performed at the 1W2B beamline of BSRF. A mobile confocal XAS endstation has been developed at this beamline (Chen et al., 2017). The confocal system restricts the probed fraction of the sample to an ellipsoidal volume allowing non-destructive depth-resolved measurements. The confocal element has a 45°/45° geometric design between the first polycapillary parallel half-lens (PCPHL) and the second PCPHL; as shown in Fig. 1, PCPHL was adjusted by a 5D stage. The characteristics of both the PCPHLs are shown in Table 1. In order to perform depth-resolved measurements, the sample holder was placed on a 3D stage. By scanning an Fe knife-edge, the diameter of the focal spot of the first PCPHL (φ₁) and the diameter of the focal spot of the second PCPHL (φ₂) can be obtained; the depth resolution d_depth can be approximately determined by φ₁ and φ₂ as follows (Peng et al., 2013),

In this work, the depth resolution was around 50 µm at 12 keV. The detector system includes an ionization chamber and a silicon drift detector (SDD). The ionization chamber, fixed in front of the first PCPHL, was used to measure the incident X-ray intensity in order to normalize the fluorescence intensity. The SDD has an energy resolution of about 125 eV at 5.9 keV and maximum count rate of 5.0 × 10⁵ s⁻¹.

Figure 1 Scheme of the confocal XRF and XAFS system.

An aqueous solution of 1 wt% HAuCl₄ was used as the sample and loaded in an in-house-developed cell made from teflon with a thickness of 1.8 mm and a diameter of 5 mm. The cell was sealed tightly with Kapton film to prevent leakage of the liquid. All measurements were carried out at room temperature. The sample cell, filled with HAuCl₄ aqueous solution, was placed in the sample holder. When the sample was moved stepwise into the confocal volume, a series of XRF spectra were collected (with an excitation energy of 12.6 keV) and the depth profile was obtained by monitoring the fluorescence intensity of the Au Lα peaks (Fig. 2). The sample surface was defined by the peak position of the differential curve of the depth profile (Mantouvalou et al., 2012; Malzer & Kanngießer, 2005). Here, in order to obtain a high-quality fluorescence signal, the point of origin (0 µm) was determined to be at the position of the maximum point of the profile. In the confocal-XRF and X-ray absorption near-edge structure (XANES) experiments, the confocal probing volume was fixed and the time-dependent Au fluorescence intensity was monitored every 5 min with a integration time of 3 s until it stabilized; the XANES spectrum at the Au L₃-edge was acquired at this point. In order to spatially explore the process of synchrotron radiation X-ray induced Au deposition, three identical HAuCl₄ aqueous solutions were prepared and moved to different depth positions at 0 µm, 50 µm and 100 µm. The XRF and XANES experiments were performed on these samples at different probing depths. In the case of self-absorption in fluorescence mode (Lühl et al., 2012), the concentration of the HAuCl₄ aqueous solution was no larger than 1 wt%, and no distortion was found in the XAS spectra. The spectra were processed using the program ATHENA (Ravel & Newville, 2005), based on the IFEFFIT library (Newville, 2001).

Figure 2 Depth profile of the Au fluorescence intensity.

After confocal-XRF and XANES experiments, the deposited Au on Kapton film was characterized by synchrotron radiation 2D X-ray contrast imaging on the 4W1A beamline of BSRF. This beamline provides a monochromatic X-ray flux of 3.5 × 10⁹ photons s⁻¹ at 8 keV with a storage ring current of 250 mA. The magnified image was recorded by a 1024 × 1024 charge-coupled device camera, corresponding to a 60 µm × 60 µm field of view. With an 880-fold magnification and a pixel size of 13.5 µm, one pixel amounts to 15 nm. The exposure time per frame was about 15 s. The sample-to-detector distance was about 30–50 cm. With a computer-controlled rotation stage and a stable mechanical design, the 2D X-ray contrast image can be automatically collected by the computer. The conventional imaging of absorption contrast was used in this experiment.

3. Results and discussion

3.1. Changes in chemical states of elemental Au in the X-ray beam path

Synchrotron monochromatic X-ray irradiation generated reducing agents such as hydrated electrons in the HAuCl₄ aqueous solution that undergo chemical reaction: Au³⁺ is transferred to Au. Depth-resolved XANES is applied to investigate the depth dependence of the chemical species of elemental Au and track the reduction of Au ions in aqueous solution. Accordingly, the Au L₃ white-line edge of Au metal is 11922 eV, whereas the white-line edge position of HAuCl₄·3H₂O has a −4 eV shift with respect to Au metal (Berrodier et al., 2005). Fig. 3 showed the XANES of the Au L₃-edge at various depths, Au⁰ was the main chemical species at depth position 0 µm. A mixture of Au⁰ and Au³⁺ existed within the depth at 50 µm. Upon further increasing of the depth position to 100 µm, the main chemical state became Au³⁺.

Figure 3 XANES spectrum of the Au L3-edge at 0 µm, 50 µm and 100 µm.

3.2. Migration of Au ions in the X-ray beam path

Table 2 shows the counts of Au Lα fluorescence intensity at the start and final stable moments for each position. In the beginning, the elemental Au was homogeneous in solution and the fluorescence intensity was almost consistent everywhere when considering the attenuation by the solution. But with increasing radiation time, they varied greatly and Fig. 4 shows their trend in detail. Also, in order to compare the trends at each depth position, the fluorescence intensities were normalized with the respective maximal values. As shown in Fig. 4, the quick rise at 0 µm indicated that the Au precipitation dominated this area. The process tended to stabilize after irradiating for 320 min. With the deeper position, the fluorescence intensity decreased to background within 140 min (depth position 50 µm) and 160 min (depth position 100 µm). These results revealed that X-ray radiation induced the heterogeneous distribution of elemental Au, which migrated toward the Kapton film window and was deposited on it within the X-ray beam.

Table 2 Normalized fluorescence intensity counts with the incident X-ray at the starting and final moment for each position Position(µm) Stablemoment Time (min) Fluorescence intensity (counts) 0 Start 0 567 Final 317 33350 50 Start 0 526 Final 157 127 100 Start 0 499 Final 174 89

Figure 4 Fluorescence intensity change with radiation time.

3.3. Process of synchrotron radiation induced Au deposition

To further understand Au deposition, we analyzed the 2D X-ray contrast image of deposited Au on the Kapton film window. As shown in Fig. 5, metallic Au was deposited on both the front and back windows. The Au deposition on the front film was significantly circular with a high-density center and slight diffusion around the perimeter. The size of the center is the same as the X-ray full-width spot with a diameter of about 100 µm; whereas on the back film, the Au deposition was dispersed and of low density, which can be explained by the divergence of the PCPHL and the attenuation of the incident beam.

Figure 5 X-ray contrast images of Au deposition on the Kapton film. Left: Au deposition on the front film window. Right: Au deposition on the back film window.

Combining the results from the XANES and XRF analyses, the process of synchrotron radiation induced Au deposition is shown in Fig. 6. X-ray irradiation of water produces reactive radicals and radical ions; the main reducing species are solvated electrons (e⁻_sol) and hydrogen radicals (Yamaguchi et al., 2016),

Solvated electrons can easily reduce metal ions down to the zero-valence atoms. As the Au atoms are formed, they act as individual centers of nucleation and further coalescence (Abedini et al., 2013). The acrylic glue on the Kapton film has potential surface adhesion forces to anchor elemental Au from the water phase, which could enhance the coalescence process and metal deposition.

Figure 6 Process of synchrotron radiation induced Au deposition.

Furthermore, the analysis by XRF indicated that the fluorescence intensity at the origin position (0 µm) was gradually increasing, and XANES shows that metallic Au dominated this area, which was further supported by the high-density image of deposited Au on the front Kapton film window. However, in the deeper layers of the liquid, the beam intensity rapidly decreased; thus, the reduced reaction rate (Au³⁺ + 3e⁻_sol → Au) could become much slower, and the Au was observed to be deposited on the back film with lower density.

With Au ion migration toward the Kapton film window within the X-ray beam path, a concentration gradient may exist in the water phase; Au³⁺ ions could move from the non-illuminated volume to the illuminated volume. Gradually, with Au deposition on the Kapton film window, the amount of Au ions not only decreased in the water phase, but also the main chemical species was Au³⁺ internally.

4. Conclusions

Confocal XRF and XAS systems were introduced to monitor the heterogeneous reduction process of tetrachloroauric solution via synchrotron radiation. Confocal micro-XRF revealed that X-ray radiation induced the heterogeneous Au distribution. Au migrated into the X-ray illuminated volume and was deposited on the Kapton film. Confocal micro-XANES examined the chemical states of elemental Au in the X-ray beam path following the reduction of Au³⁺ to Au. Furthermore, X-ray contrast imaging of the reduced Au products suggested the Au could be deposited on the Kapton film window via coalescence growth. The feasibility of this approach is demonstrated with the depth-resolved analysis of X-ray induced reduction of tetrachloroauric solutions, and promises to be a wonderful tool for the multi-dimensional analysis of X-ray stimulated processes.