Data from the spectrum.

Figure 1 shows a simulated [Reference Eggert2] spectrum of GaP with indications of how raw data are obtained for the two different Quant methods used in EDAX standardless analysis software (following the definitions in [Reference Heckel and Jugelt3]). One method is based on evaluation of the measured net-counts of element peaks above the background (P = measured counts minus the background, shown in “green”). The other method is based on peak-to-background ratios (P/B = P divided by background, shown as “green” divided by “purple”). In both cases, the measured P and P/B values are greater with higher element concentrations in the sample. But there is usually no linear relationship between element concentration and measured element X-ray signal; moreover, other elements can cause large inter-element effects. For both methods, the measured input values for the quantification calculation (net intensities or P/B) require the X-ray background to be subtracted from the gross peak. In the case of the P/B method, the peak intensity must also be divided by the background; thus, accurate background values are particularly important. If element lines overlap, a deconvolution of the peaks is required.

Figure 1: Two different quantification models, one based on evaluation of the measured net-counts of element peaks (green) and the other based on peak-to-background (P/B) ratios (green divided by purple).

Among the methods for determining the background, EDAX uses the physics-based bremsstrahlung calculation [Reference Eggert4,Reference Eggert5] and a pure mathematical background approximation method, SNIP [Reference Ryan6]. Mathematical background methods are not suitable for P/B based quantification [Reference Eggert4] because the absorption jumps at large peaks are not easily determined, but knowledge of them is required for correct calculation of proper P/B values. Peak deconvolution is performed with a probability-theory-based Bayesian algorithm [Reference Eggert and Scholz7,Reference Elam8]. Background calculation and peak deconvolution procedures are also core components of the EXpertID initial qualitative analysis of measured spectra. Also required are incomplete charge collection and pile-up corrections to the spectrum; these are related to the detector properties and the pulse processing electronics.

Corrections for matrix effects.

Two methods are available in EDAX software to convert the raw data (P or P/B) to element concentrations for bulk samples: the net-counts procedure called eZAF and the P/B-based termed PeBaZAF. Both correction procedures employ aspects of the well-known ZAF corrections [Reference Goldstein9]. The ZAF abbreviation stands for atomic number correction (Z), absorption correction (A), and secondary fluorescence correction (F).

ZAF method basics.

A classical (very simplified) formula, where N _i stands for the measured net-counts of characteristic radiation (ch) and c _i are the unknown weight fractions for elements i, is:

(1)N^{ch}_{a,i}={c_{a,i}}{\varepsilon_{i}}\,it{d\Omega\over 4\pi}\omega_i{q_i} (Z A F)^{ch}_{a,i}

where ε _i is the detector efficiency, and ${d\Omega\over 4\pi}$ is the product of the electron microscope beam-current, the measurement time, and the solid angle. The index a stands for “all” elements and indicates those values that depend on the amounts of the other elements in the specimen. ω_i is the fluorescence yield, the fraction of ionizations that result in emission of an X-ray photon, and q _i is the transition probability of an evaluated line in a line series (for example, the Kα part of K-series). An iteration is required to solve the equation system. In Equation 1, the Z describes the generated X-rays by primary electron interactions inside of the sample. The A and F factors consider the loss of X-rays due to absorption in the sample and the enhancement by secondary fluorescence caused by other generated X-rays with higher photon energies. But with classical standards-based notation, the measured net counts of the unknown sample are always related to the measured net counts from a standard sample; this is the k-ratio of standards-based analysis. We can modify Equation 1 to:

(2){N^{s}_{a,i}\over N^{st}_{i}}=K_{a,i} = c_{a,i}{(ZAF)^{s}_{a,i}\over (ZAF)^{st}_{i}}

Where s is for the sample and st stands for standard, usually a pure element standard, measured under the same conditions. Several factors cancel out because they are usually the same for measurements of the standard and the sample. With further simplification Equation 2 becomes:

(3)K_{a,i} = c_{a,i} (ZAF^{\prime})_{a,i}

The ZAFʹ factors are now all correction factors relative to the pure element standard. It is possible to take the k-ratio and divide by ZAFʹ factors to get the weight fractions of the elements in the unknown. The ZAFʹ notation of Equation 3 is still used in standardless quantification results to keep it somehow consistent with the classical standards-based formula. Nevertheless, since no standards were measured, the pure-element-related k-ratio is actually calculated via a model; it is not a really a measured value.

The eZAF method.

In this article a generically standardless-based correction factor notation is always used. The atomic number correction Z, which is in two parts, is no longer a “correction” but a calculation of primarily excited X-rays [Reference Goldstein9]. There is a calculated integral over energy-dependent cross sections that considers the stopping power for electrons in the sample, the energy lost from incident electrons. This is the S-factor calculation for all electron-generated X-ray photons. The second part of the Z factor is a separate backscatter “correction,” the R-factor [Reference Heckel and Jugelt3,Reference Goldstein9], which compensates for electrons escaping the sample and not generating X-rays. One can derive from Equation (1):

(4)N^{ch}_{a,i}={c_{a,i}}\,{\varepsilon_{i}}\,it{d\Omega\over 4\pi}\omega_i{q_i}\,\,{S^{ch}_{a,i}} (R A F)^{ch}_{a,i}

The dead-time corrected measurement time is known, but it is not usually possible to determine the beam-current exactly in an SEM. There is one more unknown parameter than the available equations, thus it is necessary to use the additional constraint that the sum of all concentrations must equal 100%. But it is possible to determine the unknown parameter indirectly with a separate reference measurement on a pure element sample under the same conditions. In the latter case, the results can be calculated as un-normalized compositions.

The eZAF method uses a Z and R calculation that follows the fundamental work by Love & Scott [Reference Love and Scott10]. The absorption correction used is based on the Sewell/Love/Scott “Quadrilateral” model for estimating the curve of generated X-rays as a function of depth [Reference Sewell11]. In the absorption correction, a more recent database of mass absorption coefficients (MACs) by Elam et al. [Reference Elam12] is also used. This is important because these MAC values can strongly affect the absorption correction. The fluorescence correction is based on [Reference Eggert and Heckel13].

Figure 2 shows a HfNi sample spectrum, and Figure 3 shows the evaluation of the spectrum with a k-ratio-based result presentation versus generic standardless notation. The internal correction calculation is same using identical models. Therefore, the results are same. The difference in the upper table is that the k-ratio notation is assuming smaller corrections in relation to an estimated pure element measurement. But this measurement was actually not performed and therefore the algorithm has calculated the k-ratio, based on a theoretical model. In the lower table of Figure 3, the correction factors in relation to generated X-rays are actually greater because standard measurements were not performed. Based on different estimated corrections, the calculated systematic error estimations are different. In the standardless notation, all R- and A-corrections are less than 1.0 (a loss from primary excited X-rays), and all F-corrections are greater than 1.0 (an enhancement of primarily excited X-rays). This is not what happens with k-ratio of ZAFʹ notation where everything is compared to pure element standards. In the standardless case, the k-ratio is a fake. It was never really measured.

Figure 2: Spectrum from a Ni/Hf sample acquired with an SDD. Accelerating voltage = 20 kV; counting time = 30 seconds; count rate 13 kcps. Calculated background and spectrum reconstruction are shown.

Figure 3: Two ways of representing standardless ZAF results. (top) Net-count-based eZAF analysis of a Ni/Hf sample with “classical” k-ratio notation; all corrections are in relation to estimated “pure” element standards (Equation 3). (bottom) Generic standardless notation where all corrections are in relation to primary electron excited X-rays (Equation 4). The standardless unnormalized results were obtained using a single reference measurement made on pure Cu to determine the absolute relation. Note that the measurement input and the final analytical results are identical. The difference is only the notation of presented factors. The calculated error is based on different assumptions for each correction. Only the second view is a correct depiction of the corrections employed in standardless case.

The P/B method.

The EDAX PeBaZAF is a P/B-method following the basic ZAF approaches, but in this case a precise measurement must be made of the bremsstrahlung background. The basic relation is given by writing Equation 4 for both P and B and dividing the equations. Thus, (P/B) _i represents the number of net characteristic (ch) peak counts divided by the measured bremsstrahlung (br) at the same energy:

(5)(P/B)_{a,i} = c_{a,i} {\omega_{i}}{q_{i}} {{S^{ch}_{a,i}}\over {S^{br}_{a,i}}} {(RAF)^{ch}_{a,i}\over {(RA)^{br}_{a,i}}}

Compared to the eZAF formula, some parameters dropped out of Equation 5 so that the number of unknown variables is equal to the number of equations. The solution does not require normalization of the composition values so that they sum to 100%. There is no physical effect to generate bremsstrahlung radiation by other X-rays (all bremsstrahlung is generated by charged particles), thus there is no F-factor for the bremsstrahlung model. This P/B model has been developed and improved from the 1980s until today [Reference Heckel and Jugelt3,Reference Eggert and Heckel13,Reference Eggert2,Reference Eggert14]. All ZAF factors within Equation 5, except the F-correction, are ratios between characteristic radiation and bremsstrahlung.

Comparison of the two methods.

Both approaches have advantages and disadvantages. The original design idea was that the P/B would always be the method of choice if the sample surface is not flat (particles, rough surfaces) because many effects in excitation and absorption cancel out. But during early work with this method, it was found that the P/B produced good accuracy [Reference Wendt15] in general, even for flat specimens. The challenge with PeBaZAF method is to extract the proper P/B values from a measured spectrum. An accurate background determination is required at the same energy as the peak, and the EDAX software provides this with an iterative bremsstrahlung calculation [Reference Eggert4]. But the small number of counts in the measured background intensity (B) significantly influences the value of P/B, causing the PeBaZAF to exhibit a worse value of precision compared to eZAF. This means that PeBaZAF has poorer repeatability, which is detrimental for comparison tasks. On the other hand, the ZAF correction in the PeBaZAF is smaller (correction factors are closer to 1), leading to fewer systematic errors and good mean accuracy. The eZAF method exhibits larger correction factors, which reduces accuracy, but it has better precision. So one could say these two methods are “complementary” [Reference Eggert16].

To evaluate the expected uncertainty with these quantitative measurements, an error parameter was calculated for each result. The parameter Err% is based on company software that combines the level of systematic error in the quantitative method with the level of precision in the measurement. Thus, if the number of counts is large enough, the precision part will be small, leaving Err% to report primarily the systematic error, which includes uncertainties with the inputs for, and the formulation of, the ZAF matrix correction method.