research papers
Silicon drift detectors as a tool for time-resolved fluorescence
on low-concentrated samples in catalysisaHamburger Synchrotronstrahlungslabor HASYLAB at Deutsches Elektronen-Synchrotron DESY, Notkestrasse 85, D-22603 Hamburg, Germany, bDESY-FEC, Notkestrasse 85, D-22603 Hamburg, Germany, and cHaldor Topsøe A/S, Nymøllevej 55, DK-2800 Kgs. Lyngby, Denmark
*Correspondence e-mail: peter.kappen@desy.de
A silicon drift detector (SDD) was used for ex situ and time-resolved in situ fluorescence X-ray absorption fine structure (XAFS) on low-concentrated catalyst samples. For a single-element and a seven-element SDD the energy resolution and the peak-to-background ratio were verified at high count rates, sufficient for fluorescence An experimental set-up including the seven-element SDD without any cooling and an in situ cell with gas supply and on-line gas analysis was developed. With this set-up the reduction and oxidation of a zeolite supported catalyst containing 0.3 wt% platinum was followed by fluorescence near-edge scans with a time resolution of 10 min each. From ex situ experiments on low-concentrated platinum- and gold-based catalysts fluorescence scans could be obtained with sufficient statistical quality for a quantitative analysis. Structural information on the gold and platinum particles could be extracted by both the Fourier transforms and the near-edge region of the spectra. Moreover, it was found that with the seven-element SDD concentrations of the element of interest as low as 100 ppm can be examined by fluorescence XAFS.
Keywords: silicon drift detectors; time-resolved; fluorescence; XAFS; in situ; catalysis; low-concentrated; gold; platinum; catalysts.
1. Introduction
X-ray absorption fine-structure (XAFS) spectroscopy is a valuable tool for studying the local structural environment around an element of interest in a multi-component catalyst (Clausen et al., 1998; Iwasawa, 1996; Prins & Koningsberger, 1988). Furthermore, electronic properties and valence states of the elements in the sample can be obtained. Most commonly, of catalyst samples is measured in a transmission experiment (Clausen et al., 1998; Iwasawa, 1996; Prins & Koningsberger, 1988). However, this method is only applicable to concentrated heterogeneous catalysts, where the element of interest has a concentration of more than about 1 wt%. The concentration limit strongly depends on the energy of the and on the absorption of the matrix atoms. In the case of low-concentrated samples, fluorescence is the preferred technique (Iwasawa, 1996; Jaklevic et al., 1977), where the use of energy-dispersive fluorescence detectors allows most of the fluorescence lines of the different elements in the sample to be clearly identified.
Fluorescence ; Gautier et al., 1996; Manceau et al., 1996; Brown et al., 1995; Leutenegger et al., 2000, and references therein; Greegor et al., 1997). In order to obtain high-quality data, in many of these systems the low concentration of the component or element of interest can be compensated by long data-acquisition times. However, this is not a viable procedure in the case of catalysis where in situ and time-resolved measurements are of particular interest. Some in situ studies using fluorescence on moderately low-concentrated heterogeneous catalyst systems (few %) are known (Thomas et al., 1994; Sankar et al., 1995; Shannon et al., 1996, 1997; Chun et al., 2001). However, only very few results at low concentrations (<1 wt%) have been reported up to now (e.g. Kappen et al., 2001; Grunwaldt, Kappen, Basini & Clausen, 2001; Grunwaldt, Kappen, Hammershøi et al., 2001; Yamagushi et al., 2000). In the case of these systems, energy-dispersive fluorescence detectors with high-count-rate performance are of major advantage.
has been applied to a variety of fields such as catalysis, biology, environmental chemistry, archeometry and geology (Iwasawa, 1996Silicon drift detectors (SDD) with an integrated junction et al., 1997; Strüder, Fiorini et al., 1998). These detectors can be operated at several hundred thousand counts per second with an appropriate energy resolution (<300 eV), while Ge-based detectors usually show less energy resolution at these count rates [e.g. measurements with a five-element high-count-rate Ge detector (model PGP 5seg h.c. from DSG) gave, with a shaping time of 250 ns at a total count rate TCR ≃ 150 kcounts s−1 and E = 5.9 keV, an energy resolution of ∼850 eV, where the corresponding detector pixel size was 100 mm2]. However, latest developments using digital signal processing electronics for a multi-element HP-Ge detector also led to a good energy resolution (390 eV at 15.77 keV) at high count rates (150 kcounts s−1) (Farrow et al., 1998). For a number of experimental environments a certain compactness of the detector system is required.
transistor (JFET) can handle high count rates (StrüderProgress has been made in the development of thermoelectrically instead of cryogenically cooled Ge-based detectors (Derbyshire et al., 1999). Also in this case the development of the SDD opens up an alternative, because it does not need any cooling (however, its performance is enhanced when using a Peltier element for cooling). Ongoing progress in parallelization through monolithic multipixel design (Hansen & Tröger, 2000; Lechner et al., 2001) will allow SDDs to cover large solid angles resulting in better counting statistics. This will give interesting opportunities for time-resolved studies on low-concentrated samples.
In this publication we report on the application of a seven-element SDD for the in situ and ex situ investigation of catalysts containing very low concentrations of noble metals. For this purpose the count-rate-dependent performance of a one-element and a seven-element SDD are also discussed and compared with a modern HP-Ge detector system.
2. Silicon drift detector
2.1. General
In order to detect fluorescence photons of the order of several keV, different approaches have been used. As a non-energy-dispersive detector, a device based on an et al. (1984). It covers a large solid angle () with simultaneously some reduction of signal contributions from of the incident X-ray beam. This detector is also applicable to fluorescence in the soft X-ray regime (Lytle et al., 1984).
has been applied by LytleHowever, energy-dispersive detectors have important advantages compared with the ionization chambers, since a unique identification of the fluorescence radiation from each of the elements in a sample becomes possible. Even in comparatively simple systems consisting of a heavy element in a light matrix, energy-dispersive detectors are highly advantageous, because the precise discrimination of the fluorescence of interest from other signals (e.g. from elastically scattered photons) results in a clear enhancement of the data quality.
Commonly, semiconductors (e.g. Si, Ge, HgI2 or GaAs) are used as detector materials, and the basic idea of operating such a detector is to use it as a reversely biased diode (see e.g. Knoll, 1979). The resulting electrical field generated is homogeneous, similar to that of a standard flat capacitor, hence leading to a comparatively large capacitance. Since the noise level and energy resolution are closely related to the capacitance of the detection system, the relatively large capacitance limits the detector performance. These limits can be overcome, e.g. by a silicon drift detector.
Fig. 1 schematically shows a pie-chart view of an SDD. Through incidence of a photon a charge cloud is generated in the n--type silicon bulk. Application of appropriate voltages to the p+ entrance window, covering one entire side of the Si chip, and to the p+ ring structure on the other side forms an inhomogeneous electrical field in the detector chip. This forces the negative charges to drift to a very small readout anode. Such a concept of charge transport was first proposed by Gatti & Rehak (1984). Silicon technology allows to monolithically integrate a JFET at the centre of the active silicon area (e.g. Lechner et al., 1996), where the anode is connected to the gate contact of the JFET. Both small readout anode and integrated JFET lead to a very low detector capacitance (<100 fF; Strüder, 2000; Strüder, Fiorini et al., 1998), so that low noise and good energy resolution can be achieved. In addition, the charge-collecting time in the SDD is short (∼100 ns; Strüder et al., 1999; Strüder, Lechner & Leutenegger, 1998), resulting in high-count-rate capabilities (several 100 kcounts s−1). Further descriptions of the silicon drift technique can be found by, for example, Lechner et al. (2001); Strüder (2000); Strüder et al. (1997, 1999); Strüder, Fiorini et al. (1998); Strüder, Lechner & Leutenegger (1998); Lechner et al. (1993, 1996); and Gatti & Rehak (1984).
2.2. SDD performance aspects: experimental
The performance of a fluorescence detector (including its subsequent electronic components such as amplifier, ADC etc.) can be evaluated, for instance, by means of the energy resolution and the peak-to-background ratio of a fluorescence line (e.g. Lep´y et al., 1999). The energy resolution ( FWHM) determines whether two fluorescence signals can be separated. The peak-to-background ratio (P/B) is a measure for the lower limit of concentration of a species which can be detected. Often P/B is defined as the of a fluorescence line divided by a mean background level in a certain energy interval (Lechner et al., 2001; Lep´y et al., 1999; Strüder, 2000). This type of definition is dependent on the energy resolution of the detector and, since the background signal is mainly caused by incomplete charge collection in the sensitive detector volume, which does not affect the FWHM, we use a modified definition, P/B := (peak integral of fluorescence line)/(integrated background), leading to values that are no longer a function of the FWHM.
Experiments to measure the FWHM and P/B on a single-pixel SDD were carried out at the bending-magnet beamline X1 (Frahm, 1989; HASYLAB, 2001) at the synchrotron radiation facility Hamburger Synchrotronstrahlungslabor HASYLAB at Deutsches Elektronen-Synchrotron DESY. The detector was provided by KETEK GmbH, Munich. As a test fluorescence sample a Zn foil was irradiated with monochromatic radiation (E = 10.5 keV), using an Si(111) double-crystal monochromator. The incident was controlled via a monochromator-stabilizer (MoStab; Krolzig et al., 1984), referring to an mounted between the monochromator and the sample. By detuning the monochromator crystals from parallel alignment, the number of photons on the Zn foil could be varied. The signal from the was used as a measure of the TCR incoming to the detector.
The detector was mounted perpendicular to the beam axis in order to minimize signals from via a fast counter (Canberra Dual Counter/Timer 1776). Since the amplifier works linearly for low count rates, the signal from the could be scaled to absolute units of TCR. An analog-to-digital converter (ADC, Silena 7423 UHS) was used to digitize the amplifier output signals, and the fluorescence spectra from the Zn sample were recorded by a multichannel analyzer (MCA, model MCD4LAP by FAST ComTec). The temperature of the SDD was varied using a Peltier element.
The output signals from the SDD were fed to a shaping amplifier (Silena 7611/L; shaping time 250 ns), and the number of incoming pulses was monitoredAnalogous experiments were carried out for a seven-element SDD (SDD chip provided by KETEK GmbH, Munich) using a sample containing 1.8 wt% Ni in a matrix of 7.1 wt% Mo/Al2O3 as a fluorescing object. Each of the individual detector pixels has a sensitive area of 5 mm2. The SDD chip is mounted in a metal housing, and it is covered by a light-tight entrance window (25 µm Kapton foil evaporated with ∼100 nm Al), since it is sensitive towards visible light. Seven independent pre-amplifiers and shaper channels (shaping time 280 ns) are also integrated in the metal housing. The necessary voltages for operation of the SDD elements are provided by one external power supply and are distributed via bond wires directly at the silicon chip. The complete system (i.e. housing of the SDD chip, power supply and amplifier and shaper electronics) was built at HASYLAB. The set-up of the further signal-processing chain is described in detail in §3.1.1 and is shown in Fig. 2 (without the Ortec 579 amplifier). No cooling was applied to the detector, which led to an SDD chip temperature of about 300 K.
2.3. SDD performance aspects: results and discussion
Results of the experiments are plotted in Fig. 3 for two detector temperatures, 293 K and 255 K.
The values of the FWHM were calculated using a Gaussian fit at the Zn K fluorescence line (8.6 keV). The values of the FWHM increase linearly with the number of incoming counts (slope 0.25×10-3 eV count−1). In general an increase of the FWHM can be explained by electronics effects, e.g. uncertainties in the baseline-restore. At TCR ≃ 150 kcounts s−1 it is found that FWHM ≃ 300 eV. At lower temperatures the energy resolution becomes significantly better, and FWHM < 300 eV can be achieved up to very high count rates of about 400 kcounts s−1 [similar to results by Strüder et al. (1997) and Lechner et al. (2001)]. Fig. 3 also shows that P/B decreases with increased TCR. The reasons for this behaviour have to be further investigated.
Results from the experiments on the seven-element SDD are shown in Fig. 4. It can be seen that the FWHM increases to ∼340 eV at 150 kcounts s−1 (with a slope of eV count−1), which is not as good as that found for the single-pixel SDD (although for low count rates the performance is found to be better, e.g. FWHM ≃ 250 eV at TCR ≃ 20 kcounts s−1). It should be noted that the signal electronics for both SDD experiments consisted of different amplifiers. Thus the increase in the FWHM is not expected to be an effect of specific pulse processing electronics. From Fig. 4 one can also see that P/B ≃ 4 is decreased in comparison with the single-pixel detector. The lower performance of the seven-element SDD is due to a strong signal from elastically scattered photons contributing to the low-energy background B, due to operating the detector chip above room temperature (∼300 K), and due to electronic effects in running a multi-element SDD instead of a single-element SDD. The voltages for operation of the seven-element SDD are generated by a common supply and then distributed to each element (see also §3.1.1). Slight electronic differences between the pixels cannot be excluded, and it was thus not possible to tune every pixel individually to its optimum performance. Hence a compromise between the detector elements had to be found.
Modern multipixel HP-Ge detector systems also show an increase of the FWHM with TCR. For instance, the 30-element HP-Ge presented by Farrow et al. (1998) exhibits a non-linearly increasing FWHM with an average slope of about 1×10-3 eV count−1 [calculated from the corresponding figures of Farrow et al. (1998) by averaging the slopes for a TCR interval of about 300 kcounts s−1]. This increase is comparable with those found for the SDDs.
The weak dependencies FWHM(TCR) found for the SDDs also imply that the use of single-channel analyzers for detecting the fluorescence intensity of interest is not usually a problem for fluorescence −1 while crossing an This has negligible influence on the fluorescence spectrum because the FWHM of the discriminated fluorescence signal changes only slightly (e.g. for the seven-element SDD: 300 eV 312 eV for 90 kcounts s−1 110 kcounts s−1 at Ni ).
(even if the SCA windows are fixed during an scan). Especially in the case of low-concentrated systems, TCR only changes by typically 10–20 kcounts sThe results from the experiments on the single-pixel SDD demonstrate that its performance is good even at very high count rates. Both the energy resolution [see also e.g. Strüder et al. (1997), Strüder, Fiorini et al. (1998), Lechner et al. (2001)] and the peak-to-background ratio [see also e.g. Kappen, Tröger et al. (2001)] were found to be very high. The properties of the seven-element SDD appear to be slightly worse compared with the single-pixel SDD. However, they still meet very well the requirements for time-resolved fluorescence studies on low-concentrated samples, e.g. catalyst samples (e.g. Kappen et al., 2001).
3. Application of a multi-element SDD: investigation of low-concentrated catalysts
For catalysis research it is seldom sufficient to know the structural details of a catalyst before and after use. For a detailed understanding of the dynamic behaviour of a catalyst it is necessary to perform time-resolved studies under reaction conditions. et al., 1998; Iwasawa, 1996; Prins & Koningsberger, 1988). For catalysts containing the element of interest in low concentrations the fluorescence detection mode is the preferred tool, and the additional need of time resolution requires a detector which allows the processing of high count rates at good energy resolution.
has been demonstrated to be particularly useful in this respect (ClausenIn the following sections the experimental set-up and conditions for the investigation of catalyst samples by a multi-element SDD will be presented. We will also show examples of noble metal catalysts investigated ex situ and in situ at the Au LIII and the Pt LIII Gold catalysts are, for instance, known to oxidize carbon monoxide at low temperatures (Haruta, 1997; Valden et al., 1998; Grunwaldt & Baiker, 1999), and platinum-based catalysts are used in hydrogenation/dehydrogenation and oxidation reactions (Ertl et al., 1997). Usually the noble metal loading is low because of the high cost of the noble metal and in order to achieve a high dispersion.
3.1. Experimental
3.1.1. Beamline and detector set-up
Catalyst samples were investigated by fluorescence et al., 1995) at HASYLAB. An Si(111) double-crystal monochromator was used for the scans and the beam intensity was controlled using a MoStab as described above (see §2.2). The undulator was operated at a gap spacing that allowed energy scans without large changes in The beam size at the sample position was fixed to 12 mm × 1 mm using a standard slit system.
at the undulator beamline BW1 (FrahmThe detector used for the experiments was the seven-element SDD introduced in §§1 and 2.3. Its signals were fed to filter amplifiers (ORTEC 579) inside the experimental hutch (see Fig. 2), providing pulses of 3 V amplitude at 10 keV photon energy. These signals could be transferred outside of the hutch without significant noise pick-up. For each detector pixel, two single-channel analysers (ORTEC Quad SCA 850) were used to discriminate the total SDD signals and the signals in the fluorescence line of interest, respectively. The TTL-output pulses from the SCAs were counted by Kinetics HEX-Counters (3610-L2A) mounted in a Camac crate. Beamline and electronics were controlled by a Linux PC. Additionally, multichannel analyzer spectra could be recorded with an ADC/MCA module (LeCroy 3512/3588).
The distance between sample and detector was about 5 cm, which corresponds to a solid angle of per pixel. As can be seen from Fig. 2, the detector was not placed exactly perpendicular to the beam axis (20°). Owing to polarization effects, this leads to some increase of the total count rate by elastic scattering.
3.1.2. Data processing
The data acquired from each of the detector pixels were corrected for the ; Zhang et al., 1992) was applied. After dead-time correction the spectra from the different detector pixels were added up using individual weighting factors, such that small weights are used for high background and/or low edge jump data, and vice versa for high- quality data. The weighting factor W was defined as the relative edge jump, W: = J/B, where J is the edge jump calculated at the edge position and B is the pre-edge background value. Per fluorescence scan, the different values of W for the different detector pixels were typically found to be very similar (). It should be noted that W is only valid for spectra that exhibit statistical uncertainties, i.e. any systematic error is neglected.
of the corresponding signal chain containing the detector pixel, amplifiers and the SCA. By irradiating a metal foil as fluorescence test sample, ≃ 700 ns was found, where the paralyzable dead-time model (Knoll, 1979Self-absorption was disregarded due to the low concentrations of the investigated elements.
3.1.3. Ex situ experiments
Samples were investigated at room temperature and in ambient air. The catalysts were pressed into pellets, each with a thickness of about 1 mm: 1 wt% Au on TiO2, 700 ppm Au plus 400 ppm Pd on Al2O3, and 157 ppm Pt plus 3340 ppm Ru on Al2O3. The Au/TiO2 sample was prepared by deposition of colloids [similar to Grunwaldt et al. (1999)] followed by drying at 323 K. For the AuPd/Al2O3 sample, Au(III) and Pd(II) precursors were deposited on the Al2O3 support and calcined at 383 K. The PtRu sample was prepared by adsorption of H2PtCl6 and RuCl3 under similar conditions as the Au/TiO2 sample and subsequent drying at 323 K.
The pellets were mounted such that their surface normal formed an angle of 45°–60° with respect to the X-ray beam axis. Fluorescence LIII edges. Each scan (scan range eV) was recorded in less than 1 h.
scans were recorded around the Au and Pt3.1.4. In situ experiments
The in situ experiments were performed on a sample containing 0.3 wt% platinum and 0.5 wt% palladium in a matrix consisting of 70 wt% Al2O3 and ∼30 wt% zeolite. The powder (sieve fraction 75–125 µm) was loaded in a quartz glass capillary of outer diameter 1.0 mm and wall thickness 0.01 mm. The capillary served both as an in situ cell for fluorescence and as a reaction cell where the temperature (up to 773 K) and gas flow (in the ml min−1 range) can be adjusted. Moreover, on-line gas analysis was performed by a (Balzers Thermostar), similarly as in previous transmission experiments (Clausen et al., 1991; Grunwaldt et al., 2000). The capillary was mounted at a 30° angle with respect to the beam axis so that a sufficiently large sample volume could be illuminated (Fig. 2).
In the first step of the in situ experiment a fluorescence scan of the sample was recorded at room temperature. Then the sample was heated in hydrogen flow (2.5 ml min−1) with a constant temperature ramp of 2.5 K min−1 up to 573 K. During this treatment, fluorescence XANES spectra were taken in the near-edge region of the platinum LIII-edge ( = 110 eV, acquisition time 10 min per spectrum). At 573 K and after subsequently cooling the sample to room temperature, additional fluorescence scans were recorded ( = 600 eV, acquisition time ≃ 45 min).
In the second step of the in situ experiment the same sample was heated in a flow of 500 ppm SO2 in air (2 ml min−1) with a constant temperature ramp of 2.5 K min−1 up to 653 K. Again, fluorescence XANES spectra were recorded in the near-edge region of the Pt LIII-edge while heating up, and finally fluorescence spectra were measured both at 653 K and at room temperature.
3.2. Results and discussion
3.2.1. Ex situ investigation of gold- and platinum-based catalysts
Ex situ fluorescence spectra with the corresponding MCA spectra for the Au/TiO2, AuPd/Al2O3 and PtRu/Al2O3 samples are shown in Figs. 5, 6 and 7, respectively. The MCA spectra in all three examples exhibit the fluorescence line of the element of interest to be well separated from the signals originating from matrix elements or elastically scattered photons. Note that in the case of the alumina supported catalysts no matrix signals can be observed, since Al K fluorescence radiation is too low in energy to be able to penetrate the ambient air and the window material of the detector. Minor fluorescence lines and/or lines of ambiguous origin are labelled in brackets. The fluorescence spectra exhibit relative noise amplitudes1 of 10-2–10-3, and therefore structures can be well extracted. After background removal using spline functions, Fourier transforms of the k1-weighted -functions for the gold-containing samples were calculated (k = 2.5–12.0 Å-1). The results are depicted in Fig. 8(a).
The fluorescence ) exhibits a distinct white line which indicates that gold is in an oxidized state. The corresponding Fourier transform (Fig. 8a) reveals two major peaks at 1.7 Å and 3.2 Å. The comparison with transforms of reference spectra from metallic gold and from Au2O3 (Fig. 8b) indicates that the catalyst sample contains both metallic gold and gold in a higher oxidation state.
spectrum of the gold-containing alumina sample (Fig. 6In contrast to this sample, the Au/TiO2 catalyst does not contain gold in an oxidized state as indicated by the absence of a white line in the fluorescence scan (Fig. 5). The corresponding Fourier transform supports this conclusion, because no contribution is found at 1.7 Å (Fig. 8a). This shows that the preparation process using colloidal gold deposition (Grunwaldt et al., 1999) with subsequent mild drying results in metallic gold particles on the titania support.
Results obtained from the third sample (PtRu/Al2O3; Fig. 7) exhibit a pronounced white line, which indicates that platinum is not in the fully reduced state. When platinum catalysts are reduced, typically a decrease in the intensity of the white line can be observed (Bazin et al., 1996, 1999).
The results demonstrate that good quality fluorescence ), which allows structural changes to be followed in situ and even allows on-line gas monitoring, as it is important in the field of catalysis (Grunwaldt et al., 2001). These properties and the current further development of monolithic multi-element SDDs with even more pixels (Hansen & Tröger, 2000; Lechner et al., 2001) show that SDDs are an interesting alternative to other fluorescence detectors [Lytle type, Si(Li), HP-Ge etc.]. As outlined in the Introduction, ongoing development in the field of Ge detectors also results in systems with high-count-rate performance and compact cooling (Farrow et al., 1998; Derbyshire et al., 1999) which are thus useful for similar applications as the SDDs.
spectra, using the seven-element SDD, can be obtained at concentrations as low as 100 ppm. They also show that the detector is well suited for time-resolved studies of the investigation of atoms incorporated in heavy matrices. This is not only due to its high-count-rate performance, but also because it is quite handy (no cooling system). Hence, it can be used in combination with a reaction cell (see §3.1.4Presently, most of the time-resolved et al., 1998; Iwasawa, 1996; Prins & Koningsberger, 1988). The lower limit of concentration in solid samples is, however, typically found to be at about 1 wt% in the case of heavy matrix elements (Kappen et al., 2001) and at about 1000 ppm for a light matrix (e.g. Brown et al., 1988, and references therein). This also becomes obvious from Table 1, showing relative edge jumps Jr,fluo and Jr,transm of the scans on the three samples investigated ex situ. Hence, fluorescence is also a better alternative in this case.
experiments are performed in the transmission mode (Clausen
|
The lowest concentration at which it is possible to record good quality fluorescence e.g. Ti, V, Mn) a light filter foil (e.g. C or Al) placed between sample and detector can be used to reduce the fluorescence from the matrix atoms considerably, hence leading to a significant decrease in the total count rate. This may allow the total of primary photons on the sample to be increased, resulting in an increase of the count rate of the element of interest. The option of using light-element filters is especially interesting for the study of heavier elements, e.g. noble metals in a light matrix, where the filter is almost transparent for the fluorescence radiation from the metal atoms but opaque to the fluorescence from the matrix. Aluminium filters were successfully applied to investigate gold in MnO2 (Grunwaldt et al., 2002). Light-element filter foils are not useful if the fluorescence lines from the matrix and the element of interest are close together.
data depends on the experimental set-up, the detection geometry and the matrix surrounding the element of interest. In the case of heavy matrix elements their fluorescence intensity dominates the total count rate at the detector. For samples with comparatively heavy matrix elements (It should be noted that the option of balancing the count rates from the matrix and the element of interest by the use of filters does not diminish the need for high-count-rate detectors. Such detectors are indispensible for applications at high-flux X-ray light sources, e.g. at undulator beamlines.
3.2.2. In situ studies of a platinum-based catalyst during reduction and oxidation
Figs. 9(a) and 9(b) show the XANES spectra recorded during the temperature-programmed reaction, i.e. the application of a linear heating ramp under the corresponding reaction conditions. Using a heating ramp of 2.5 K min−1, in every 25 K interval a XANES spectrum was obtained. One can clearly see how the white line at the Pt LIII-edge decreases upon reaction in H2 (indicating reduction of the Pt) and subsequently increases (indicating oxidation) upon treatment in SO2/air at increasing temperature. The fluorescence spectrum after oxidation in SO2/air is very similar to the starting spectrum before reduction in H2 (not shown in a separate figure). The continuous decrease and increase of the white line during the in situ experiment reveals that, within the time resolution, both processes occur smoothly with no intermediate steps as, for example, observed for catalysts with low copper concentration (Kappen et al., 2001; Yamagushi et al., 2000). The reduction starts already at quite low temperatures (<323 K). Similarly the oxidation proceeds smoothly, starting at a temperature below 373 K. Bazin et al. (1996, 1999) also studied the reduction of platinum by analysis of the white-line intensity. They found the reduction occurring above 423 K, proceeding rapidly in the beginning and going on more slowly until 573 K. The catalyst in this study seems to be reduced much easier, which can be due to, for example, the particle size and the preparation procedure. However, differences in the reaction cell geometry may also explain the discrepancies. This will be studied in more detail in the future.
4. Conclusion
In the present study it was shown that multi-element silicon drift detectors with an integrated JFET are a very good tool for time-resolved in situ fluorescence studies on elements present in low concentrations in catalysts. A fluorescence set-up including a seven-element SDD and an in situ cell with gas supply and on-line gas analysis was developed for these purposes. Detector operation without cooling and at a total count rate of up to more than 100 kcounts s−1 per element is possible. Even under these conditions the energy resolution is sufficient to separate the fluorescence lines of most elements encountered in catalysts.
The in situ reduction and oxidation of a zeolite-supported catalyst containing only 0.3 wt% platinum could easily be followed by this technique. Owing to the detector properties, fluorescence XANES spectra ( = 100 eV) with good statistical quality (relative noise 10-2) could be obtained. Within the time resolution of 10 min per scan, the reduction and oxidation of platinum occurred smoothly, as revealed by the decrease and increase of the white line. Thus, fluorescence using the in situ set-up can provide short-range-order information of a catalyst simultaneously to its catalytic properties.
Furthermore, results from ex situ fluorescence investigations of low-concentrated gold and platinum catalysts on alumina and titania supports were obtained. The recorded spectra are of sufficient quality (relative noise ) to allow Fourier transforms and quantitative analysis. This made it possible to distinguish between oxidation states of gold in samples prepared by different preparation modes. It appears that under typical experimental conditions concentrations of the element of interest as low as 100 ppm can be measured by fluorescence using a multi-element SDD.
Further applications and improvement of fluorescence
in combination with on-line catalysis will benefit from the current development of a 61-element SDD. This detector will give new possibilities, especially in connection with high-photon-flux light sources like undulator beamlines.Acknowledgements
Experimental assistance from A. Kjersgaard and S. Rokni is gratefully acknowledged. We also would like to thank KETEK GmbH and MPI-Halbleiterlabor, Munich, for providing the silicon drift detector chips, for general support and for the cooperation within which the data for Fig. 3 were recorded. Also financial support by Dansync is gratefully acknowledged (JDG and BSC).
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