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Journal logoJOURNAL OF
SYNCHROTRON
RADIATION
ISSN: 1600-5775
Volume 5| Part 3| May 1998| Pages 845-847
https://doi.org/10.1107/S0909049597013125

Initial data from the 30-element ORTEC HPGe detector array and the XSPRESS pulse-processing electronics at the SRS, Daresbury Laboratory

R. C. Farrow,a* J. Headspith,a A. J. Dent,a B. R. Dobson,a R. L. Bilsborrow,a C. A. Ramsdale,a P. C. Stephenson,a S. Brierley,a G. E. Derbyshire,b P. Sangsingkeowc and K. Buxtonc

aCLRC, Daresbury Laboratory, Warrington WA4 4AD, UK, bCLRC, Rutherford Appleton Laboratory, Chilton, Oxon OX11 0QX, UK, and cEG&G ORTEC, Midland Road, Oak Ridge, TN, USA
*Correspondence e-mail: r.c.farrow@dl.ac.uk

(Received 4 August 1997; accepted 13 November 1997)

Following the completion of the collaborative project between CLRC Daresbury Laboratory and EG&G ORTEC to develop the world's first 30-element HPGe detector for fluorescence XAFS, it has now been tested and commissioned at the SRS. The system was commissioned with the XSPRESS digital pulse-processing electronics and this has demonstrated processed count rates in excess of 10 MHz. Initial data have been recorded and are presented.

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1. Introduction

XAFS is now a mature scientific technique, performed almost exclusively at synchrotron radiation sources, which gives information on the local structure around an atom of interest. Where the atom of interest is present in the sample in low concentrations, fluorescence XAFS is used. In the case of minimally scattering samples, such as dilute aqueous solutions, the lower XAFS analysis limit for the atom of interest is dictated by the intensity of X-rays delivered to the sample. However, if this intensity is sufficiently high or the sample scatters heavily, the limitation becomes the total throughput of the detection system.

Prior to the ultra-dilute spectroscopy (UDS) station 16.5 and the XSPRESS (Farrow et al., 1995[Farrow, R., Derbyshire, G. E., Dobson, B. R., Dent, A. J., Bogg, D., Headspith, J., Lawton, R., Martini, M. & Buxton, K. (1995). Nucl. Instrum Methods, B97, 567-571.]) detector system being available at the SRS, these lower limits were realistically around 1 mM for aqueous solutions and 1000 p.p.m. for highly scattering samples.

In order to reduce these limits we need to increase the photon processing rate of the system. However, if we are to do this without compromising the energy resolution of the system, few options are open. The `brute force' approach is to increase the number of parallel detection channels (Cramer et al., 1988[Cramer, S. P., Tench, O., Yocum, M. & George, G. N. (1988). Nucl. Instrum. Methods, A266, 586-591.]; Derbyshire et al., 1992[Derbyshire, G. E., Dent, A. J., Dobson, B. R., Farrow, R. C., Felton, A., Greaves, G. N., Morrell, C. & Wells, M. P. (1992). Rev. Sci. Instrum. 63, 814-815.]). A more novel approach is to increase the efficiency of the signal processing chain by using optimized digital signal processing (Stein et al., 1996[Stein, J., Scheuer, F., Gast, W. & Georgiev, A. (1996). Nucl. Instrum. Methods, B113, 141-145.]). We have embraced both these approaches in the detector system for UDS at Daresbury and the increased processing rate that this yields, coupled with the increased flux available from the UDS station, allows us to push the concentration limits down significantly.

2. The 30-element XSPRESS detector system

2.1. Detector

The detector for ultra-dilute spectroscopy has been developed through a collaboration between EG&G ORTEC and CLRC Daresbury Laboratory. This detector has 30 parallel detection channels in a 50 mm diameter active area with each germanium crystal being 6 mm in diameter. A number of developments have been built into this detector in order to maximize its throughput, including high gain (12 mV keV−1), low-rise-time (200 ns), fast-reset (3 µs) POF preamplifiers. The finished detector has an average energy resolution of 248 eV at Fe55 at 4 kHz input with a 0.5 µs shaping time constant. A photograph is given in Fig. 1[link].

[Figure 1]
Figure 1
Photograph of the 30-element detector showing the entrance window and preamplifiers.

2.2. Signal processing

The XSPRESS signal processing departs from the conventional fixed-dead-time analogue pulse processing by using adaptive digital signal processing techniques. These allow us to implement variable-bandwidth variable-dead-time algorithms for processing events.

The signal from the detector preamplifier is converted to a digital representation using a NIM-based 12-bit analogue-to-digital converter (ADC), sampling at 10 MHz. The resulting digital data are passed to the XSPRESS VME card where events are first recognized and then processed. The strength of the XSPRESS system is that for each event, the process algorithm used is selected according to the time available. Thus, for an event which is closely followed by a successive event, a very short, wide-bandwidth algorithm is used, whereas for an event that is essentially isolated, a much longer, narrow-bandwidth algorithm is used. This results in a system which suffers much less pileup than conventional systems allowing higher throughput, but where each event is processed to its optimum energy resolution. Fig. 2[link] shows a diagram of one channel of the system.

[Figure 2]
Figure 2
Block diagram showing operation of one channel of the XSPRESS digital pulse-processing system.

The throughput of this system is given by the following equation:

[R_o=[R_i\exp(-T_dR_i)]\bigg[1-{R_iGE\over(DNR/T_r)-R_iGE}\bigg],]

where Ro is the processed event output rate of the system, Ri is the incident photon rate on the detector, G is the event gain at the preamplifier output in mV keV−1, E is the average energy of the input spectrum in keV, DNR is the dynamic range of the preamplifier, Tr is the reset time of the preamplifier with no incident photons, Td is the minimum process dead time associated with each event.

The first half of the equation is the well known throughput equation of a paralysable detector system (Knoll, 1989[Knoll, G. F. (1989). Radiation Detection and Measurement. New York: Wiley.]). However, the second half is a correction required as the reset dead time in POF systems is not negligible at high rates and, as the system takes longer to reset at these rates, this becomes a significant effect.

Although Td is a minimum process dead time, the processing may continue for a longer period. However, as the processing can take as little as Td, it is this minimum value that dictates the maximum output rate.

The peak shapes obtained are different from those normally gained from fixed-dead-time algorithm systems. This is because the peaks within this system are due to the superposition of all the peaks arising from the different algorithms available to the system. As the input rate increases, the peak shape changes due to the use of different combinations of the algorithms. Fig. 3[link] gives a theoretical representation of the peak shape at four different input rates.

[Figure 3]
Figure 3
Diagram showing how the output peak shape changes with rate for the XSPRESS system.

3. Tests

3.1. System performance

In order to evaluate the operating parameters of the system, the detector collected fluorescence and scattered radiation from a zirconium foil. The intensity of the radiation was varied by opening or closing the slits which defined the size of the incident beam. The input rate was calculated from the ion-chamber output and the dead-time-corrected intensity was recorded for a range of input intensities. Figs. 4[link], 5[link] and 6[link] indicate how the output rate, the energy resolution and the peak shift all vary with input rate. In Fig. 4[link], an average of all 30 channels was used; however, in Figs. 5[link] and 6[link], randomly selected channels 0 and 26 were used.

[Figure 4]
Figure 4
Graph showing the average throughput of all 30 channels of the XSPRESS system at Zr Kα (15.77 keV).
[Figure 5]
Figure 5
Graph showing the FWHM resolution against output rate of two randomly selected channels of the XSPRESS system at Zr Kα (15.77 keV).
[Figure 6]
Figure 6
Graph showing the peak shift against output rate of two randomly selected channels of the XSPRESS system at Zr Kα (15.77 keV).

3.2. Dilute aqueous solution

In order to demonstrate the use of the system for XAFS, a number of scans of aqueous K2(Pt)Cl4 were collected. Fig. 7[link] shows the background-subtracted XAFS of a 100 mM solution which has been collected at output rates of 10, 44 and 192 kHz. In each case the data comprise a single scan collected in 20 min.

[Figure 7]
Figure 7
Comparison of background-subtracted XAFS of 100 mM K2(Pt)Cl4 solution taken at three different input rates.

4. Results and discussion

Fig. 4[link] shows that the system throughput fitted well to the theory if a process dead time of 450 ns and a reset dead time of 3.12 µs were assumed. Deviation at the top of the graph was probably due to multiple events occurring within the resolving time of the processor.

The resolution in Fig. 5[link] was slightly worse than calculated (~2.1% as opposed to 1.8%) but this was probably due to the ADCs running under sub-optimal conditions. The peak shift in Fig. 6[link] was within the calculated limits for the system.

Although the comparison of the XAFS of the Pt solution in Fig. 7[link] showed close correlation of the collected data, the process dead time used in the relinearization algorithm was too short (300 ns) and as such the amplitudes of the oscillations were still compressed slightly at higher rates.

The system is presently undergoing further final commissioning and these results are very much preliminary. Optimum performance will be achieved by improving a number of parameters, including energy resolution, where cooling issues with the ADC units are being addressed, fluorescence windowing, where channel gains need fine trimming, and relinearization, where an ideal processing value for each channel will be determined and used.

5. Conclusions

We have presented data from the world's first 30-element high-purity detector for fluorescence XAFS combined with the XSPRESS digital signal processing electronics. This has only come about through both an extensive collaboration between EG&G ORTEC and CLRC and the development of highly efficient digital pulse-processing techniques.

References

First citationCramer, S. P., Tench, O., Yocum, M. & George, G. N. (1988). Nucl. Instrum. Methods, A266, 586–591.  CrossRef CAS Web of Science
 First citationDerbyshire, G. E., Dent, A. J., Dobson, B. R., Farrow, R. C., Felton, A., Greaves, G. N., Morrell, C. & Wells, M. P. (1992). Rev. Sci. Instrum. 63, 814–815.  CrossRef Web of Science
 First citationFarrow, R., Derbyshire, G. E., Dobson, B. R., Dent, A. J., Bogg, D., Headspith, J., Lawton, R., Martini, M. & Buxton, K. (1995). Nucl. Instrum Methods, B97, 567–571.  CrossRef Web of Science
 First citationKnoll, G. F. (1989). Radiation Detection and Measurement. New York: Wiley.
 First citationStein, J., Scheuer, F., Gast, W. & Georgiev, A. (1996). Nucl. Instrum. Methods, B113, 141–145.  CrossRef Web of Science

© International Union of Crystallography. Prior permission is not required to reproduce short quotations, tables and figures from this article, provided the original authors and source are cited. For more information, click here.

Journal logoJOURNAL OF
SYNCHROTRON
RADIATION
ISSN: 1600-5775
Volume 5| Part 3| May 1998| Pages 845-847
https://doi.org/10.1107/S0909049597013125
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