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Comparison of different excitation modes for the analysis of light elements with a TXRF vacuum chamber

Published online by Cambridge University Press:  22 May 2015

J. Prost ,
P. Wobrauschek  and
C. Streli
J. Prost*
Affiliation:
Atominstitut, Vienna University of Technology, Stadionallee 2, 1020 Vienna, Austria
P. Wobrauschek
Affiliation:
Atominstitut, Vienna University of Technology, Stadionallee 2, 1020 Vienna, Austria
C. Streli
Affiliation:
Atominstitut, Vienna University of Technology, Stadionallee 2, 1020 Vienna, Austria
*
a) Author to whom correspondence should be addressed. Electronic mail: [email protected]
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Abstract

The aim of this work was to compare different excitation modes for the analysis of light elements from carbon (Z = 6) upwards using a total reflection X-ray fluorescence analysis (TXRF) vacuum chamber which allows the attachment of different X-ray tubes and detectors. In the first set of experiments, two water-cooled high-power X-ray tubes with Cr (Z = 25) and Cu (Z = 29) anodes, respectively, were compared with an air-cooled low-power tube with Mo anode (Z = 42) and a thin Be window for the transmission of Mo-L lines. In the first two cases, monochromatic radiation was used for excitation, while in the case of the Mo tube the multilayer acted as a cut-off reflector and part of the Mo bremsstrahlung continuum together with the Mo-L series were used for excitation. Multi-element standards containing elements ranging from Na (Z = 11) to Ti (Z = 22) were analyzed by a silicon drift detector (SDD) with a 300 nm ultrathin polymer window (UTW). Detection limits were calculated and compared for the three excitation modes. The second set of experiments was performed using an air-cooled low-power X-ray tube with Rh anode (Z = 45) in order to show that a conventional SDD with a 25 μm beryllium window can be used for the detection of elements from Na upwards. The use of compact air-cooled low-power X-ray tubes together with Peltier-cooled SDDs with UTW should lead to the development of highly sensitive tabletop vacuum TXRF spectrometers with a design optimized for the analysis of light elements. Detection limits as achieved by vacuum chambers using conventional water-cooled high-power tubes (e.g. Streli et al., 2004) are realistically achievable with the new approach.

Keywords

Total Reflection X-ray Fluorescence Analysis (TXRF)low Z elementslow-power X-ray sourcesexcitation modes
Type
Technical Articles
Information
Powder Diffraction , Volume 30 , Issue 2 , June 2015 , pp. 93 - 98
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Copyright
Copyright © International Centre for Diffraction Data 2015 

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References

IAEA (1995). QXAS Software Package, International Atomic Energy Agency, Vienna.Google Scholar
Knoth, J. and Schwenke, H. (1978). “An X-ray fluorescence spectrometer with totally reflecting sample support for trace analysis at the ppb level,” Fresenius Z. Anal. Chem. 291, 200204.Google Scholar
Krause, M. O. (1979). “Atomic radiative and radiationless yields for K and L shells,” J. Phys. Chem. Ref. Data 8, 307327.CrossRefGoogle Scholar
Rauwolf, M., Vanhoof, C., Tirez, K., Maes, E., Ingerle, D., Wobrauschek, P., and Streli, C. (2014). “Total reflection X-ray fluorescence measurements of S and P in proteins using a vacuum chamber specially designed for low Z elements,” Spectrochim. Acta B 101, 118122.CrossRefGoogle Scholar
Rieder, R., Ladisich, W., Wobrauschek, P., Streli, C., and Kregsamer, P. (1993). “A multifunctional vacuum chamber for total-reflection X-ray fluorescence analysis in various excitation and detection geometries for detection limits in the femtogram range,” Nucl. Instr. Meth. Phys. Res. A 327, 594599.CrossRefGoogle Scholar
Streli, C., Pepponi, G., Wobrauschek, P., Beckhoff, B., Ulm, G., Pahlke, S., Fabry, L., Ehmann, Th., Kanngießer, B., Malzer, W., and Jark, W. (2003). “Analysis of low Z elements on Si wafer surfaces with undulator radiation induced total reflection X-ray fluorescence at the PTB beamline at BESSY II,” Spectrochim. Acta B 58, 21132121.CrossRefGoogle Scholar
Streli, C., Wobrauschek, P., Pepponi, G., and Zoeger, N. (2004). “A new total reflection X-ray fluorescence vacuum chamber with sample changer analysis using a silicon drift detector for chemical analysis,” Spectrochim. Acta B 59, 11991203.Google Scholar
Wastl, A., Stadlbauer, F., Prost, J., Horntrich, C., Kregsamer, P., Wobrauschek, P., and Streli, C. (2013). “Nanoliter deposition unit for pipetting droplets of small volumes for total reflection X-ray fluorescence applications,” Spectrochim. Acta B 82, 7175.CrossRefGoogle Scholar
Wobrauschek, P. (2007). “Total reflection X-ray fluorescence analysis – a review,” X-ray Spectrom. 36, 289300.Google Scholar