A previous paper portrayed sample preparation by fusion methodology and the X-ray fluorescence (XRF) spectrometry analytical conditions for the calibration of cement materials[1]. Experiments were conducted according to the guidelines of two well-known cement chemical analysis International Standard Methods and results were presented. The results proved that this robust analytical method is able to qualify by the ASTM C 114[2] and ISO/DIS 29581-2[3] norms.
This analytical method was developed using a Claisse® M4TM fluxer, an automated fusion instrument for the sample preparation and the Zetium, Wavelength Dispersive X-Ray Fluorescence (WDXRF) spectrometer, for the determination of all the elements of interest relating to the cement industry. The method was used to prepare finished products, process materials, as well as a very large range of raw materials which will be described in this second paper. Cement, blended cement, cement with additions, aluminate cement, clinker, kiln feed, raw mix, limestone, gypsum, sand, clay, bauxite, silica fume, slag, fly ash and iron ore are among the raw materials covered by this analytical application. This sample preparation was also transferred and optimized for TheOx® fluxer, a fully electric fusion instrument, by executing a robust validation of the method’s performance.
Due to the fact that powders are affected by mineralogy and particle size effects[4, 5], it is almost impossible to use a single XRF calibration curve for the analysis of such a wide range of different materials using the pressed powder preparation method. When fused in a borate glass, all mineralogy and particle size effects are eliminated. A single XRF calibration curve covering the whole range of concentrations for all elements of interests for the cement industry raw materials analysis can be made.
This paper examines all the XRF analytical conditions for the calibration of the entire range of raw materials using the robust borate fusion sample preparation methodology as well as the numerous Reference Materials (RMs) used for this analytical application. The results of this general and unique XRF raw materials calibration will also be presented in terms of precision, accuracy, and limit of detection.
All information regarding instruments, sample preparation methodology development, final optimized conditions of using a Claisse® M4 fluxer and robustness analysis of the preparation method for sample preparation by fusion was presented in the previous paper[1].
In the following, a sequential WDXRF spectrometer with a rhodium end-window X-ray tube of 1000 watts was used for data generation. The spectrometer analytical conditions, peak-line, background measurements, background position, pulse-height, counting time and other parameters were defined and optimized by the wavelength step-scanning of standard disks representative of the application. The spectrometer analytical conditions for the measurement of all the elements used for the raw materials application were presented in a previous paper[6]. The analytical lines for certain elements were added to the analysis method because the reference values for these elements were available from the raw materials RMs. The measurements were executed under vacuum using a 28 mm collimator mask.
The calibration of the WDXRF raw materials application was executed using a wide variety of RMs from the following origins:
Table 1 demonstrates the certified element concentration ranges in both the original sample base and the ignited base.
Compound | Concentration Range of the Certified Reference Materials | |
---|---|---|
Original Sample Base (%) | LOI Free Base (%) | |
SiO2 | 0,02 - 99,78 | 0,03 - 99,86 |
Al2O3 | 0,004 - 85,07 | 0,005 - 85,32 |
Fe2O3 | 0,005 - 85,3 | 0,005 - 91,03 |
CaO | 0,006 - 70 | 0,006 - 98,58 |
MgO | 0,001 - 21,25 | 0,001 - 39,66
|
SO3 | 0,02 - 46,3 | 0,02 - 58,54 |
Na2O | 0,001 - 4,81 | 0,001 - 4,84 |
K2O | 0,001 - 4,99 | 0,001 - 5,02 |
TiO2 | 0,004 - 3,76 | 0,004 - 3,77 |
P2O5 | 0,003 - 8,42 | 0,003 - 8,62 |
Mn2O3 | 0,0001 - 4,93 | 0,0002 - 5,05 |
SrO | 0,001 - 0,638 | 0,001 - 0,649 |
Cr2O3 | 0,0002 - 0,474 | 0,0004 - 0,486 |
ZnO | 0,0001 - 0,107 | 0,0001 - 0,109 |
ZrO2 | 0,005 - 0,14 | 0,005 - 0,2 |
V2O5 | 0,0006 - 0,72 | 0,0007 - 0,75 |
BaO | 0,0012 - 0,66 | 0,0012 - 0,66 |
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Learn more about the Zetium Cement Edition, our cement XRF analyzer.
A previous paper portrayed sample preparation by fusion methodology and the X-ray fluorescence (XRF) spectrometry analytical conditions for the calibration of cement materials[1]. Experiments were conducted according to the guidelines of two well-known cement chemical analysis International Standard Methods and results were presented. The results proved that this robust analytical method is able to qualify by the ASTM C 114[2] and ISO/DIS 29581-2[3] norms.
This analytical method was developed using a Claisse® M4TM fluxer, an automated fusion instrument for the sample preparation and a Wavelength Dispersive X-Ray Fluorescence (WDXRF) spectrometer, for the determination of all the elements of interest relating to the cement industry. The method was used to prepare finished products, process materials, as well as a very large range of raw materials which will be described in this second paper. Cement, blended cement, cement with additions, aluminate cement, clinker, kiln feed, raw mix, limestone, gypsum, sand, clay, bauxite, silica fume, slag, fly ash and iron ore are among the raw materials covered by this analytical application. This sample preparation was also transferred and optimized for TheOx® fluxer, a fully electric fusion instrument, by executing a robust validation of the method’s performance.
Due to the fact that powders are affected by mineralogy and particle size effects[4, 5], it is almost impossible to use a single XRF calibration curve for the analysis of such a wide range of different materials using the pressed powder preparation method. When fused in a borate glass, all mineralogy and particle size effects are eliminated. A single XRF calibration curve covering the whole range of concentrations for all elements of interests for the cement industry raw materials analysis can be made.
This paper examines all the XRF analytical conditions for the calibration of the entire range of raw materials using the robust borate fusion sample preparation methodology as well as the numerous Reference Materials (RMs) used for this analytical application. The results of this general and unique XRF raw materials calibration will also be presented in terms of precision, accuracy, and limit of detection.
All information regarding instruments, sample preparation methodology development, final optimized conditions of using a Claisse® M4 fluxer and robustness analysis of the preparation method for sample preparation by fusion was presented in the previous paper[1].
In the following, a sequential WDXRF spectrometer with a rhodium end-window X-ray tube of 1000 watts was used for data generation. The spectrometer analytical conditions, peak-line, background measurements, background position, pulse-height, counting time and other parameters were defined and optimized by the wavelength step-scanning of standard disks representative of the application. The spectrometer analytical conditions for the measurement of all the elements used for the raw materials application were presented in a previous paper[6]. The analytical lines for certain elements were added to the analysis method because the reference values for these elements were available from the raw materials RMs. The measurements were executed under vacuum using a 28 mm collimator mask.
The calibration of the WDXRF raw materials application was executed using a wide variety of RMs from the following origins:
Table 1 demonstrates the certified element concentration ranges in both the original sample base and the ignited base.
Compound | Concentration Range of the Certified Reference Materials | |
---|---|---|
Original Sample Base (%) | LOI Free Base (%) | |
SiO2 | 0,02 - 99,78 | 0,03 - 99,86 |
Al2O3 | 0,004 - 85,07 | 0,005 - 85,32 |
Fe2O3 | 0,005 - 85,3 | 0,005 - 91,03 |
CaO | 0,006 - 70 | 0,006 - 98,58 |
MgO | 0,001 - 21,25 | 0,001 - 39,66
|
SO3 | 0,02 - 46,3 | 0,02 - 58,54 |
Na2O | 0,001 - 4,81 | 0,001 - 4,84 |
K2O | 0,001 - 4,99 | 0,001 - 5,02 |
TiO2 | 0,004 - 3,76 | 0,004 - 3,77 |
P2O5 | 0,003 - 8,42 | 0,003 - 8,62 |
Mn2O3 | 0,0001 - 4,93 | 0,0002 - 5,05 |
SrO | 0,001 - 0,638 | 0,001 - 0,649 |
Cr2O3 | 0,0002 - 0,474 | 0,0004 - 0,486 |
ZnO | 0,0001 - 0,107 | 0,0001 - 0,109 |
ZrO2 | 0,005 - 0,14 | 0,005 - 0,2 |
V2O5 | 0,0006 - 0,72 | 0,0007 - 0,75 |
BaO | 0,0012 - 0,66 | 0,0012 - 0,66 |
As previously published[1], it was determined that ignition of the sample is absolutely necessary in the analytical process for a global fusion method. This critical step allows fusion of the raw materials and cements with additions, which are difficult or impossible to fuse in the non-ignited state with traditional fusion methods. A preparation with a sample to flux ratio of 1:10 requires a fusion program of approximately 13 minutes of heating at more or less 1050°C to prepare stable glass disks with high alumina and/or high silica samples. The cooling process is attained with forced air in 5 minutes.
To demonstrate the robustness of this fusion methodology, more than 200 different samples from 20 different material types were fused with the global fusion method.
The materials are listed in Table 2. This list includes materials not commonly used as raw materials, but sometimes found in waste materials and used as fuel to test the limits of the global nature of the method.
# | Material Type | Tried | Success |
---|---|---|---|
1) | Cement | 118 | 118 |
2) | Cement with AdditionsA | 15 | 15 |
3) | Aluminate Cement | 7 | 7 |
4) | Clinker | 13 | 13 |
5) | Kiln Feed/Raw Mix | 11 | 11 |
6) | Limestones | 9 | 9
|
7) | Gypsum | 7 | 7 |
8) | Clay | 7 | 7 |
9) | Bauxite | 4 | 4 |
10) | Sand | 7 | 7 |
11) | Silica Fume | 3 | 3 |
12) | Fly Ash | 9 | 9 |
13) | SlagB | 8 | 6 |
14) | Iron OreC | 19 | 12 |
15) | Other | 5 | 5 |
Overall | 242 | 233 |
Table 3 enumerates the inter-element corrections that were used as well as their type. Also displayed are the squared correlation coefficients from the calibration curves of the analyzed elements for the optimized selection of RMs.
Element Line | Inter-element Correction Information | Squared Correlation Coefficient | |
---|---|---|---|
Al Kα | Fixed Alphas | --- | 1,0000 |
Ba Lα | Fixed Alphas | Overlap for Ti | 0,9982 |
Ca Kα | Fixed Alphas | --- | 1,0000 |
Cr Kα | Fixed Alphas | Overlap for V | 0,9997 |
Fe Kα | Variable Alphas | --- | 1,0000 |
K Kα | Fixed Alphas | --- | 0,9999 |
Mg Kα | Fixed Alphas | --- | 0,9999 |
Mn Kα | Fixed Alphas | Overlap for Cr | 0,9998 |
Na Kα | Fixed Alphas | --- | 0,9998 |
P Kα | Fixed Alphas | --- | 1,0000 |
S Kα | Variable Alphas | --- | 1,0000 |
Si Kα | Variable Alphas | --- | 1,0000 |
Sr Kα | Fixed Alphas | --- | 0,9995 |
Ti Kα | Fixed Alphas | --- | 0,9999 |
V Kα | Fixed Alphas | Overlap for Ba & Ti | 1,0000 |
Zn Kα | Fixed Alphas | --- | 0,9986 |
Zr Kα | Fixed Alphas | Overlap for Sr | 0,9988 |
From the calibration of the different elements, three (3) correlation curves of corrected concentrations vs certificate concentrations are of particular interest. The CaO curve (Figure 2), since it is the major constituent of cement products, the SiO2 curve (Figure 3), because silica variable mineralogy influences the XRF count intensities[4], and the SO3 curve (Figure 4), seeing that sulfur, under its different oxidation states, has the reputation to be a volatile compound[5].
Figure 1. CaO correlation curves of corrected concentrations vs certificate concentrations
Figure 2. SiO2 correlation curves of corrected concentrations vs certificate concentrations
Figure 3. SO3 correlation curves of corrected concentrations vs certificate concentrations
Table 4 illustrates the results obtained from assessing sensitivity, precision and accuracy. Using the spectrometer software, the sensitivity results were captured using the Lower Limit of Detection (LLD). Precision was evaluated on an absolute concentration base (%) by calculating the maximum difference between the results of the analyzed elements for the duplicate preparations of all referencematerials used in the calibration. The precision evaluation was executed for both the M4TM and the TheOx® fluxers. The accuracy evaluation was determined on an absolute concentration base (%) by calculating the maximum difference of the two results obtained from the duplicates on both the M4TM and the TheOx® fluxers, against the certified value over all the reference materials used in the calibration. The standard deviation was calculated by the software and is also presented in this table.
Compound | LLD
(ppm) |
Max. Dev.A Between Duplicates M4 (%) |
Max. Dev.A Between Duplicates TheOx (%) |
Software
Standard Deviation (%) |
Max. Dev.A
from Certified Value (%) |
---|---|---|---|---|---|
SiO2 | 40 | 0,10 | 0,15 | 0,16 | 0,59 |
Al2O3 | 61 | 0,11 | 0,16 | 0,105 | 0,34 |
Fe2O3 | 51
|
0,12 | 0,11 | 0,089 | 0,36 |
CaO | 41 | 0,17 | 0,19 | 0,16 | 0,34 |
MgO | 84 | 0,04 | 0,04 | 0,081 | 0,22 |
SO3 | 47 | 0,11 | 0,05 | 0,062 | 0,19 |
Na2O | 85 | 0,02 | 0,02 | 0,018 | 0,07 |
K2O
|
17 | 0,02 | 0,02 | 0,011 | 0,04 |
TiO2 | 42 | 0,02
|
0,01 | 0,0130 | 0,06 |
P2O5 | 58 | 0,02 | 0,03 | 0,0074 | 0,03 |
Mn2O3 | 25 | 0,009 | 0,012
|
0,012 | 0,04
|
SrO | 14 | 0,01 | 0,006 | 0,0044 | 0,014 |
Cr2O3 | 34
|
0,006
|
0,005 | 0,0024 | 0,008 |
ZnO | 13
|
0,003 | 0,002 | 0,0010 | 0,003 |
ZrO2 | 11
|
0,002 | 0,002 | 0,0032 | 0,007 |
V2O5 | 15 | 0,003 | 0,001 | 0,0019 | 0,004 |
BaO
|
57 | 0,01 | 0,006 | 0,0060 | 0,014 |
A. Max. Dev. = Maximum Deviation.
The results proved excellent accuracy and precision despite the wide range of elements.
A global fusion/XRF analytical method for cement industry materials has been described in this paper as well as in the previous paper[1]. This method of preparation by fusion allows fusing cements and all raw materials that are normally found in a cement plant. The cement
calibration complies with the precision and accuracy requirements of the International Standard Methods for cement analysis (ISO/DIS 29581-2 and ASTM C 114).
In this paper, it was proven that it is possible to obtain a precise and accurate universal calibration, able to cover the wide range of raw materials used by the global cement industry. The range of materials include cement, blended cement, cements with additions, aluminate cement, clinker, kiln feed, raw mix, limestone, gypsum, sand, clay, bauxite, silica fume, slag, fly ash and iron ore, just to name a few.
1. BOUCHARD, M., ANZELMO, J.A., RIVARD, S., SEYFARTH, A., ARIAS, L., BEHRENS, K., DURALI-MÜLLER, S., “Global Cement and Raw Materials Fusion/XRF Analytical Solution”, Advances in X-ray Analysis, Vol. 53, Proceedings of the 58th Annual Conference on Applications of X-ray Analysis (Denver X-ray Conference), International Centre for Diffraction Data, ISSN 1097-0002, 2010, pp. 263-279.
2. ASTM, Standard C 114-08, “Standard Test Methods for Chemical Analysis of Hydraulic Cement”, Annual Book of ASTM Standards, Volume 04.01, ASTM International, West Conshohocken, PA, 2008, pp. 150–157.
3. DIN EN ISO 29581-2 (Draft standard, 2007-07), “Methods of testing cement - Chemical analysis of cement - Part 2: Analysis by X-ray fluorescence” (ISO/DIS 29581-2:2007), 30 pp.
4. ANZELMO, J.A., “The Role of XRF, Inter-Element Corrections, and Sample Preparation Effects in the 100-Year Evolution of ASTM Standard Test Method C114”, Journal of ASTM International, Vol. 6, No. 2, Paper ID JAI101730, available online at www.astm.org, 2009, pp. 1-10.
5. SPANGENBERG, J. and FONTBOTÉ, L., “X-Ray Fluorescence Analysis of Base Metal Sulphide and Iron-Manganese Oxide Ore Samples in Fused Glass Disc”, X-Ray Spectrometry, Vol. 23, 1994, pp. 83-90.
6. BOUCHARD, M., ANZELMO, J.A., RIVARD, S., SEYFARTH, A., ARIAS, L., BEHRENS, K., DURALI-MÜLLER, S., “Global Cement and Raw Materials Fusion/XRF Analytical Solution. II”, Powder Diffraction, Vol. 26, No. 2, International Centre for Diffraction Data ISSN 0885-7156, 2011, pp. 176-185.0,0002 - 5,05