Introduction |
This application note gives all recommended data for the described analytical task, including the list of measured values based on certified reference samples. |
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Alloy system Au-Ag-Cu-Zn |
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The Analytical problem |
Analysis of gold alloys is an important task in the jewellery and other industries for determining alloy composition and monetary value. The four component alloy system examined here very often will be used. The addition of Zn to the Au-Ag-Cu basic system can influence the mechanical properties. |
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From the analytical point of view, the resolution of Gold „L“, the Copper „K“ and Zinc „K“ lines is the main problem. |
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The analytical instrument |
Measurements are made with the benchtop spectrometers |
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X-Ray ComPact |
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X-Ray Karatmeter |
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A low power tube is used in either instrument in excitation mode. A special collimator reduces the exciting beam down to 0.5 mm diameter. In this way, analysis of irregular or filigree samples will be possible. This is very important for jewellery manufacturers and others producing fine intricate products. |
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Energy dispersive measurement is made with a proportional counter. Despite the limited resolution of this type of detector, highly precise analysis is possible if the qualitative composition of the sample is known. Good statistical measurement guarantees high reproducibility. |
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Max. Layer Thickness: approx. 12 µm |
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Sample preparation |
The surface of the samples should be thoroughly cleaned free of contaminants. This will enable the irradiated area to be representative of the whole. |
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Further preparation is not necessary as the very small excited area and the use of normalised intensities reduce the geometric influence of the signal. |
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The irradiated area must be homogeneous. Non-homogenities can produce insufficient reproducibility of measurement. |
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Excitation conditions |
| Voltage |
40 kV |
| Power |
approx. 15 W |
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Program Parameters |
| Program |
XMasteR |
| Evaluation program |
ALLOY.EXE |
| Measuring time for references |
180 s |
| Measuring time for analysis |
120 s |
| Normalisation parameter |
1 |
| Number of calibration ranges |
2 |
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| Parameter |
Au |
Ag |
Cu |
Zn |
| Deconvol |
ON |
ON |
ON |
ON |
| Cmin |
30 |
0 |
0 |
0 |
| Cmax |
100 |
50 |
60 |
55 |
| ROI Intmin |
188 |
364 |
130 |
140 |
| ROI Intmax |
212 |
404 |
150 |
160 |
| ROI Decmin |
100 |
350 |
100 |
100 |
| ROI Decmax |
270 |
450 |
270 |
270 |
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Calibration |
The relatively wide concentration range for Gold will be divided into two calibration ranges. The first ranges from 100 to 40 %, the second from 40 - 30 %. |
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For every range a few reference samples are necessary. A total of more than 15 samples will be used for this calibration. |
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Analytical results |
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Accuracy |
Calibration curve |
In the following figure the gold calibration curve is shown. |
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Error of fit |
The following values for error of fit are reached for the whole calibration range of the different elements.
[Wt %]
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| Element |
Au |
Ag |
Cu |
Zn |
| Error of fit |
0.13 |
0.13 |
0.20 |
0.25 |
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This means, that for the alloy system described here the analytical error is in the range of + 0.20 Wt.% for gold. |
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The accuracy is a little lower for the other elements but these elements do not determine the value of the alloy. |
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For repeated measurements on the same sample, the following results were obtained using 120 s measuring times. |
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Standard deviation |
| Au-Concentration |
0.08 % Gew. % |
| Rel. Standard deviation Au-Intensity |
0.30 % |
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