EXAFS analysis using FEFF and FEFFIT

Newville, M.

doi:10.1107/S0909049500016290

invited papers

JOURNAL OF
SYNCHROTRON
RADIATION

ISSN: 1600-5775

Volume 8| Part 2| March 2001| Pages 96-100

doi:10.1107/S0909049500016290

EXAFS analysis using FEFF and FEFFIT

Matthew Newville ^a ^*

^aConsortium for Advanced Radiation Sources, The University of Chicago, 5640 South Ellis Avenue, Chicago, IL 60637, USA
^*Correspondence e-mail: newville@cars.uchicago.edu

(Received 26 July 2000; accepted 7 November 2000)

Some of the advanced EXAFS analysis features of FEFF and FEFFIT are described. The scattering path formalism from FEFF and cumulant expansion are used as the basic building blocks of EXAFS analysis, giving a flexible and robust parameterization of most EXAFS problems. The ability to model EXAFS data in terms of generalized physical variables is shown, including the simultaneous refinement of two different polarizations for Co [K] EXAFS data of $[\rm CoPt_{3}]$ .

Keywords: XAFS; FEFF; FEFFIT.

1. Introduction

The use of ab initio calculations of scattering phase shifts and amplitudes for EXAFS analysis has become standard practice in the past decade. Though scattering phase shifts and amplitudes derived from experiment or tables (McKale et al., 1988 ) are still in use, ab initio calculations from the programs EXCURVE (Binsted et al., 1991 , 1992 ; Binsted & Hasnain, 1996 ), GNXAS (Filipponi et al., 1995 ) and especially FEFF (Zabinsky et al., 1995 ) have come to dominate the field. In the proceedings of the XAFS X conference (Hasnain et al., 1999 ), for example, of the quantitative EXAFS analyses¹ presented, more used FEFF than all other methods combined. Use of experimental and tabulated standards were each below 10%, and use of the ab initio codes EXCURVE and GNXAS were each below 15%.

These statistics reflect a change in the field that is unlikely to be reversed soon. To understand and use XAFS at this time, one must come to understand FEFF, its strengths and its limitations. This is not to imply that using FEFF is always the best way to analyze XAFS data, or that having one theoretical program dominating the field is necessarily good. Still, even if one does not use FEFF, one must understand the physical approximations implemented in the code well enough to assess results based on it.

The widespread use of FEFF may be related to it being only a theoretical code, with no analysis program included as part of an integrated package, as both EXCURVE and GNXAS provide. Instead, many analysis programs (George & Pickering, 1995 ; Bouldin et al., 1995 ; Michalowicz, 1995 ; Vaarkamp et al., 1994 ; Ressler, 1997 ; Newville et al., 1995 ) can use the results of FEFF. This separation of ab initio theory from analysis allows quite a bit of flexibility, but puts more burden of understanding the calculation details on the user, or at the least authors of analysis programs.

While the theoretical understanding of X-ray absorption that leads to reliable and efficient computation of the XAFS phase shifts and amplitudes from FEFF is well documented (Rehr & Ankudinov, 2001 ; Rehr & Albers, 2000 ), comparatively little has been published about the use of FEFF for EXAFS analysis. One early study (O'Day et al., 1994 ) is notable for its demonstration of the suitability of FEFF in analyzing real EXAFS data. Comparisons of theoretical phase shifts from different calculations have been made (Vaarkamp et al., 1994; Vaarkamp, 1993 ), but are rare. Some comparisons of different potential models within FEFF have been made (Bridges & Rehr, 1998 ), but are largely anecdotal.

In this paper, I will describe some of the practical aspects of using FEFF for EXAFS analysis. The emphasis here is not on the physics underlying the calculations performed by FEFF, but on how these results are applied to analyzing EXAFS data. Though FEFF is in constant development, version 7.02 will be used in this work. I will also describe the EXAFS analysis program FEFFIT (Newville et al., 1995), which extends the utility of FEFF and adds the ability to parameterize and fit XAFS data to FEFF calculations. Special attention will be placed on the advanced modeling capabilities of FEFFIT, including the use of `generalized fitting parameters' and the simultaneous refinement of multiple data sets.

2. The outputs of FEFF

As an ab initio calculation, FEFF uses a list of atomic coordinates in a cluster and physical information about the system such as absorbing atom and excited core-level for its calculation. For crystalline systems, generating a list of atomic coordinates is simplified by the program ATOMS (Ravel, 2001 ) which generates the required coordinates (as well as reasonable defaults for most FEFF parameters) starting from a crystallographic description of the system.

FEFF (versions 5 through 7) calculates EXAFS using four internal modules: POTPH, PATHS, GENFMT and FF2CHI. POTPH creates atomic potentials based on the geometrical distribution of atoms, overlaps their wavefunctions, and calculates the scattering phase-shifts based on these potentials. Electronic models including exchange energies and inelastic processes are used, and much of the fundamental research and published literature on FEFF is devoted to these parts of the calculation (Rehr et al., 1986 , 1991 , 1992 ; Ankudinov & Rehr, 1995 ; Ankudinov, Conradson et al., 1998 ). For the purposes here, POTPH generates the file phase.bin, which is unreadable by humans, but used in later parts of the calculation. For better XANES calculations, FEFF8 (Ankudinov, Ravel et al., 1998 ) breaks POTPH into three modules, but the outcome for EXAFS analysis is still phase.bin.

The PATHS module (Zabinsky et al., 1995) identifies all single- and multiple-scattering paths for an arbitrary cluster of atoms. Many candidate scattering paths are efficiently rejected at this stage on the basis of a quick estimate of the scattering amplitude. In addition, degenerate paths that will give identical XAFS contributions are recognized at this stage, resulting in a handful of scattering paths that dominate the EXAFS even out to the fourth-neighbor distance in well ordered systems. The geometries of the unique paths are written to the file paths.dat, sorted by distance from the absorbing atom. This file can be very helpful in identifying and describing the path geometries.

The GENFMT module (Rehr & Albers, 1990 ) uses the results of POTPH (phase.bin) and PATHS (files.dat) to calculate the XAFS contribution from each path. Though the full complex fine-structure $[\tilde\chi(k)]$ is calculated directly for each path from the potentials and scattering phase shifts, the results are broken down at this stage so as to be described by a simplified version of the familiar EXAFS equation for each path j,

$[\tilde\chi_j(k) = {{N_j\,F_j(k)\exp{[-2R_j/\lambda(k)]}}\over{kR_j^2}} \exp{[i2kR_j + i\delta_j(k)]}.\eqno(1)]$

Here, N_j is the number of equivalent paths, F_j(k) is the effective scattering amplitude, $[\delta_j(k)]$ is the effective total phase shift (including contributions from the central atom and all scattering atoms), and R_j is half the total length of the scattering path. In principle, both F_i and $[\delta_i]$ will have some dependence on the distance between atoms, but any R dependence of these terms is left out of this simple expression. No thermal or configurational disorder is included at this point.

In equation (1), k is the wavenumber and $[\lambda(k)]$ is the mean free path of the photoelectron. These both depend on the details of the potentials for the cluster, but are independent of scattering path. The EXAFS contribution for each path is written to the file FEFFnnnn.dat, where nnnn is replaced by the path index j. The file list.dat (or files.dat in earlier versions of FEFF) gives a simple list of the feffnnnn.dat files including R_j and the number of legs in the path.

FF2CHI, the final module of FEFF, performs the relatively simple sum over paths j to generate the complex $[\tilde\chi(k)]$ ,

$[\tilde\chi(k)=\textstyle\sum\limits_j\tilde\chi_j(k) \exp({-2k^2\sigma_j^2}),\eqno(2)]$

which can be compared with experimental $[\chi(k)]$ by taking the imaginary part. Here, disorder can be added through a Debye–Waller factor to give the EXAFS a realistic decay. Values for $[\sigma_j^2]$ can be given explicitly, or calculated using a Debye or Einstein model. The results are written to the file chi.dat, which contains arrays for k, $[{\rm Im}[\tilde\chi(k)]]$ , $[|\chi(k)|]$ and the phase of $[\tilde\chi(k)]$ .

2.1. The structure of feffnnnn.dat

For EXAFS analysis, either the full chi.dat or the individual feffnnnn.dat files can be used. Many analysis programs use the chi.dat as this resembles experimentally derived standards for EXAFS. Though convenient, this is not a very flexible approach, and is not well suited to including the effects of large disorder. The preferred method is to use the feffnnnn.dat files. The structure of these files, shown in Fig. 1, is somewhat complex. In order to recover the variables in equation (1) from the data in this file, the mapping shown in Table 1 is used. The k-dependent arrays in feffnnnn.dat are given on a coarser grid than is typically used for XAFS, but are smooth enough functions of k that linear interpolation can be used. In addition to the variables in equation (1), the complex photoelectron wavenumber, p(k), is also defined here, and will be used below to modify (1). k is purely real, relative to the onset of absorption at the Fermi level, and so is comparable with the experimentally determined k. It is used to reconstruct $[\tilde\chi(k)]$ as calculated by FEFF. p is complex (the imaginary part representing losses of photoelectron coherence including the mean free path and core-hole lifetime), relative to the continuum level E₀, and the more appropriate measure of photoelectron momentum to use for the modification of equation (1).

Table 1
Correspondence of the variables in equation (1) to the entries of a feffnnnn.dat file

Variable	Value from feffnnnn.dat
R_j	reff
N_j	deg
k	k
F_j(k)	mag[feff] * `red factor'
$[\delta_j(k)]$	real[2*phc] + phase[feff]
$[\lambda(k)]$	lambda
p(k)	real[p] + i/lambda

Figure 1
Sample feffnnnn.dat: feff0001.dat for first-neighbor Co–Co scattering in $[\rm CoPt_{3}]$ . After a series of comment lines ending with the line -----, the number of legs, number of equivalent paths, half path-length R_j (2.7089 Å here), Norman radius and Fermi energy relative to E₀ are given, followed by coordinates of the atoms in the path, and then a list of k-dependent arrays (truncated here) used to reconstruct $[\tilde\chi_j(k)]$ .

2.2. Polarization dependence in FEFF

FEFF can accurately calculate the polarization dependence of EXAFS, as well as related techniques such as X-ray magnetic circular dichroism (Ankudinov & Rehr, 1997 ). For [K] -edge calculations at sufficiently high k, the usual $[\cos^2(\alpha)]$ dependence (Stern, 1988 ) of the angle $[\alpha]$ between scattering path and polarization directions works very well. Using FEFF's polarized calculations for [K] -edge EXAFS is not much of an improvement over simply multiplying the unpolarized calculation by $[\cos^2(\alpha)/3]$ . The factor of three can lead to some confusion, as FEFF will always report the full coordination shell, even though some of the atoms do not contribute.² The polarization of L_II and L_III edges is somewhat more complex (Stern, 1988; Rehr & Albers, 2000), including isotropic as well as a $[\cos^2(\alpha)]$ term. The relative sizes of these terms depends on the scattering matrix elements and whether the $[p\rightarrow{s}]$ transitions are included (Ankudinov & Rehr, 1997).

3. The structure of FEFFIT

FEFFIT essentially replaces the FF2CHI module of FEFF, expanding the EXAFS equation (1) and enhancing the sum over paths of equation (2) using a set of feffnnnn.dat files. Even in the simplest respect of forward-modeling XAFS spectra, FEFFIT has several advantages over the FF2CHI module of FEFF, including the ability to combine calculations from different FEFF runs (as for different central-atom locations in systems with multiple sites), and the ability to Fourier transform theoretical spectra (both total and individual paths, and with and without `phase corrections') into $[\chi(R)]$ .

Since the feffnnnn.dat files represent the EXAFS from a path with exact atomic coordinates, any thermal or configurational disorder must be added at this stage. Indeed, information about the partial pair distribution function g(R) of atoms around the absorbing atom is often the goal of EXAFS analysis. FEFFIT uses the cumulant expansion (Bunker, 1983 ; Kendall, 1958 ) which is independent of any model for g(R) and converges with a small number of cumulants for small and moderate disorders. The first four cumulants ( $[\Delta R]$ , $[\sigma^2]$ , C₃ and C₄) of the distribution g(R) can be determined with FEFFIT, though C₄ is rarely important.

There are two subtle but important points to be considered when using the cumulant expansion in systems with large disorder. First, the 1/kR² dependence of $[\chi(k)]$ must be included. This can be performed simply and accurately (Tranquada & Ingalls, 1983 ) by adding a term of the form $[-2k\sigma^2/ R]$ to $[\Delta R]$ . The second point is specific to using ab initio calculations from which losses can be described in terms of a mean free path: the complex p should be used instead of k to model the disorder. This mixes the phase and amplitude effects of each of the cumulants, which can be important for large disorder. The resulting modified EXAFS equation is

$[\eqalignno{\tilde\chi_j(k)=&{} {{S_{0j}^2\,N_j\,F_j(k)}\over{k(\Delta R_j+R_j)^2}} \exp{\{i[2kR_j+\delta_j(k)]\}} \cr&{\times}\exp{[i(2p\Delta R_j - 4p\sigma_j^2/R_j - 4p^3C_{3j}/3)]} \cr&{\times}\exp{[-2R_j/\lambda(k) - 2p^2\sigma_j^2 - 2p^4C_{4j}/3]}.&(3)}]$

As noted above, both k and p are used here. Although p is used to modify the EXAFS based on the cumulants, we must first reconstruct $[\tilde\chi_j(k)]$ from the feffnnnn.dat files according to equation (1). In addition to the four cumulants, values for a constant amplitude factor S₀², an energy shift E₀ which will modify the values of k used, and a broadening energy term E_i which will modify $[\lambda(k)]$ , can be modified for each path j. Thus, up to seven path parameters can be used to modify the EXAFS contribution for each path.

3.1. Path parameters and generalized variables

Though useful for modeling, the seven independent path parameters available in FEFFIT for each scattering path are more than can usually be determined from real EXAFS data. The limited amount of information available from EXAFS data can be described using the number of independent parameters that can be obtained from a periodic signal (Lytle et al., 1989 ; Brillouin, 1962 )

$[N_{\rm info}\simeq 2\Delta k \,\Delta R/\pi,\eqno(4)]$

where $[\Delta k]$ and $[\Delta R]$ are the extent of the data in k- and R-space under consideration, respectively.³

The approximate nature of equation (4) should be emphasized, especially as noise in the data is not considered here. The suggestion (Stern, 1993 ) that more parameters can be determined than is given by (4) has not proven particularly beneficial. More sophisticated statistical treatments (Curis & Benazeth, 2000 ) may be helpful for assessing how many and what parameters can be obtained from EXAFS data, but have proven difficult to implement for general analysis of individual spectra. Methods explicitly taking the entropy of the spectra into account (Krappe & Rossner, 2000 ) may also prove useful in quantifying the number of parameters that can be obtained from a given spectra, and have the potential of being able to take noise into account.

Because of the limited information in EXAFS, it is not meaningful to adjust all seven path parameters independently, especially when scattering paths involving different neighboring atoms overlap in a `shell'. Many parameters (notably E_i, C₄ and often C₃) will not need adjustment at all. In addition, several parameters for different paths may take the same value or values that are simply related. Therefore, a system with constraints and algebraic relations between the parameters of a single path, different paths or even different sets of data is desirable. FEFFIT allows the path parameters for each path to be written as algebraic expressions of a set of `generalized variables', which can be varied to fit a set of data. The effect of the generalized variables on the path parameters can be quite complex, but a simple example would be to use one E₀ and one S₀² parameter for all paths in a fit. Such a constraint is not necessarily required, but commonly used.

FEFFIT's system of generalized variables and user-defined expressions for path parameters gives a wide range of possible constraint equations, allows physically meaningful sets of variables to be fit directly from XAFS data, and helps to limit the number of free parameters in a fit. Several examples (Frenkel et al., 1994 ; Ravel et al., 1999 ; Kelly et al., 1998 ) have used FEFFIT's advanced modeling capabilities. Many of these examples rely on the important ability of FEFFIT to simultaneously refine multiple sets of data. A simple example will be given in §4.

3.2. Approaches to fitting and error analysis

FEFFIT combines and modifies the EXAFS from a set of feffnnnn.dat files to best-fit experimental $[\chi(k)]$ data. Recently, FEFFIT has also been used with experimental standards as described elsewhere in these proceedings (Frenkel et al., 2001 ). The fit can be performed on data in k-, R- or back-transformed k-space. In general, fitting in R-space gives the most satisfactory results, the most control over what portion of the spectra is studied, and the most meaningful error analysis. The fitting is performed with the Levenberg–Marquardt (Marquardt, 1963 ) method of non-linear least-squares minimization. Given the set of P generalized variables $[{\bf x}]$ , the most likely values $[{\bf x}_0]$ are those found to minimize

$[\chi^2 = {{N_{\rm info}}\over{N}} \sum_{i = i'}^{N+i'-1} \left[{ { \tilde\chi_{\rm data}(R_i) - \tilde\chi_{\rm model}(R_i,{\bf x})}\over{\varepsilon_i}}\right]^2\eqno (5)]$

where $[\tilde\chi(R)]$ represents the real and imaginary components of the Fourier transform of $[\chi(k)]$ and $[\varepsilon]$ is the estimated uncertainty of the data (Newville et al., 1999 ). The sum for $[\chi^2]$ is performed over a finite range of R. For multiple-data-set fits, the sum for $[\chi^2]$ is extended to include a sum over data sets in addition to the sum of data points for individual spectra. Modifications to the low-R components of $[\chi(k)]$ can be made using the AUTOBK (Newville et al., 1993 ) algorithm. Though rarely altering the fit results, this allows correlations between background and structural variables to be assessed.

Estimates for $[{\bf\delta x}]$ , the uncertainties of the fitted variables $[{\bf x}]$ , and $[{\bf C}({\bf x}_i,{\bf x}_j)}]$ , the correlations between variable pairs, are made at the `best fit' condition ( $[{\bf x} = {\bf x}_0]$ ), according to the standard statistical treatment of experimental data (Bevington, 1969 ). Because the estimate of the uncertainty of the data is not always reliable, the uncertainties estimated this way are rescaled by $[{\chi^2/\nu}^{1/2}]$ where $[\nu=N_{\rm info}-P]$ . Both $[\chi^2]$ and $[\chi^2/\nu]$ are reported, as is an EXAFS $[\cal R]$ factor that gives the misfit relative to the data size.

4. Example: anisotropy in CoPt₃: Co K edge

As an example, we study the anisotropy in the Co and Pt distribution in CoPt₃ films, grown along the (100) direction (Cross et al., 2001 ). Without addressing too many of the material science points of interest (Rooney et al., 1995 ; Shapiro et al., 1996 ; Meneghini et al., 1999 ; Tyson et al., 1996 ), the goal for the EXAFS analysis is to investigate any difference in Co–Co pairing in and out of the growth plane. In a fully disordered state, CoPt₃ assumes an f.c.c. lattice, with random population of Co and Pt. A fully ordered L1₂ structure (similar to the ordered Cu₃Au phase) is an f.c.c. lattice with Co on cube corners and Pt on cube faces.

Polarized EXAFS measurements were made at Advanced Photon Source sector 20 (PNC-CAT) at both the Co [K] edge and Pt L_III edges for a set of four samples (each with different substrate temperatures during deposition), with the polarization vector of the incident X-rays perpendicular to and parallel to (within $[5^{\circ}]$ ) the (100) plane (Cross et al., 2001). Because of the simple cos² dependence of the [K] -edge polarization (as opposed to the somewhat more complicated L_III-edge polarization), unpolarized FEFF calculations were performed for the Co edge, and the polarization dependence will be included explicitly with FEFFIT. This allows one feffnnnn.dat file to be used for near-neighbor Co and one for near-neighbor Pt, simplifying the problem somewhat. Unpolarized FEFF7 calculations were used.

Starting from the L1₂ structure, we define $[\alpha]$ as the fraction of Co in-plane near neighbors, and $[\beta]$ as the fraction of Co out-of-plane near neighbors. For each of the four in-plane neighbors (Fig. 2a), and for the eight out-of-plane neighbors (Fig. 2b), we have

$[\chi_{\rm IP} = \alpha \chi_{\rm Co} + (1-\alpha) \chi_{\rm Pt},\eqno(6)]$

$[\chi_{\rm NP} = \beta \chi_{\rm Co} + (1-\beta) \chi_{\rm Pt},\eqno(7)]$

and the total first-shell EXAFS for the two different polarizations (explicitly including the polarization dependence) is simply

$[\eqalignno{&\chi_{\parallel}= {({3\rm{N_{\parallel}}}/{2})} [\alpha\chi_{\rm{Co}} + (1-\alpha)\chi_{\rm{Pt}}] + 3{\rm{N_{\perp}}} \left[\beta\chi_{\rm{Co}} + (1-\beta)\chi_{\rm{Pt}}\right], \cr&\chi_{\perp} = {({3{\rm{N_\perp}}}/ 2)}\left[\beta\chi_{\rm Co} + (1 - \beta)\chi_{\rm Pt}\right].&(8)}]$

Data for both polarizations were fit simultaneously, using two paths ( $[\chi_{\rm Co}]$ and $[\chi_{\rm Pt}]$ ) for each polarization. This constrains $[\alpha]$ and $[\beta]$ to be self-consistent. The overall amplitude factor was set as the product of S₀² and the coefficients in equation (8). The following variables were used in the fits: E₀ [one used for both data sets after carefully checking the alignment of the starting $[\mu(E)]$ spectra], R_Pt, R_Co, $[\sigma^2_{\rm Pt}]$ , $[\sigma^2_{\rm Co}]$ , $[\alpha]$ and $[\beta]$ . S₀² itself was fixed at 0.74 by asserting that the total number of neighbors for the sample grown at 1073 K (which is expected to be well annealed and fully disordered) was 12. Though FEFF does account for many loss terms in the EXAFS, this is a fairly typical value for S₀², and may include systematic errors in normalization as well as an incomplete accounting of the loss terms. The total numbers of in-plane neighbors $[N_{\|}]$ and out-of-plane neighbors $[N_{\bot}]$ were also varied in the fit.

Figure 2
In-plane (a) and out-of-plane (b) scattering paths for CoPt₃. In the ordered structure, Co is completely surrounded by Pt, as shown.

Fig. 3 shows a portion of the feffit.inp file setting up this model, including the polarization dependence. The fit results for the CoPt₃ sample grown at a substrate temperature of 723 K are shown in Table 2, and the final fit of $[\chi(R)]$ is shown in Fig. 4. The values for the best-fit statistics were $[\chi^2]$ = 392, $[\chi^2_\nu]$ = 39 and $[{\cal R}]$ = 0.003.

Table 2
Summary of fit results for Co [K] -edge EXAFS of CoPt₃ grown with a substrate temperature of 723 K

Variable	Best-fit value	(uncertainty)
$[\alpha]$	0.48	(0.10)
$[\beta]$	0.12	(0.09)
R_Pt	2.691	(0.004)
R_Co	2.671	(0.008)
$[\sigma^2_{\rm Pt}]$	0.007	(0.001)
$[\sigma^2_{\rm Co}]$	0.009	(0.002)
$[N_{\\|}]$	3.35	(0.20)
$[N_{\bot}]$	7.87	(0.33)
E₀	2.04	(0.23)

Figure 3
Portion of feffit.inp setting up the fitting model for the Co [K]

-edge of CoPt₃ described in equation (8)

. The fitting model is dominated by the calculation of the amplitude parameters for the in-plane and out-of-plane Co–Co and Co–Pt contributions. a represents $[\alpha]$ and b represents $[\beta]$ . Note that the polarization dependence here is particularly easy as the f.c.c. structure fixes all angles to be $[\pi/4]$ or $[\pi/2]$ .

Figure 4
Data (dashed) and first-shell fit (solid) of in-plane (a) and out-of-plane (b) Co EXAFS for a sample grown with a substrate temperature of 723 K. The fit R-ranges are indicated by vertical bars and the contributions from the Co and Pt neighbors are shown inverted. The Fourier transforms were performed on $[\chi(k)]$ data with k_min= 1.0 Å⁻¹, k_max = 10.0 Å⁻¹, dk = 0.3 Å⁻¹ for Hanning windows, and k-weight = 2.

5. Conclusions

The use of FEFF and FEFFIT has been described and demonstrated for a simultaneous fit of two polarizations of Co [K] -edge EXAFS of CoPt₃. FEFFIT adds robust data modeling and fitting capabilities to FEFF while retaining a high level of precision. Despite the wide use of both FEFF and FEFFIT, there has been little formal training for using these programs, and little effort to make them accessible to novices. A recent series of workshops (Ravel, 2000 ), this paper, and the recently released IFEFFIT program (Newville, 2001 ) are attempts to overcome these shortcomings.

Footnotes

¹That is, analyses in which numerical results were derived from $[\chi(k)]$ . Theoretical papers and XANES analyses were not included. 109 of the 242 papers in the proceedings met these criteria. Of these, 70 used FEFF, 15 EXCURVE, 7 GNXAS, 8 McKale et al. (1988) and 9 experimental or unspecified standards.

²In a simple cubic material, [K] -edge EXAFS with the polarization vector along (100) would only be sensitive to two near-neighbor atoms. FEFF will report that six neighbors contribute.

³It is occasionally thought that this limitation is due to the Fourier transform performed during analysis, and that by analyzing data in E- or k-space this limitation can be avoided. This notion is wrong. The limitation is due to the finite extent of g(R) for a given shell, not the data processing methods. A measurement of $[\mu(E)]$ may contain 400 independent measurements of $[\mu(E)]$ , but it does not give 400 independent samples of the first-neighbor distance.

Acknowledgements

I thank John Rehr, Edward Stern, Bruce Ravel, Steve Zabinsky, Alex Ankudinov and Julie Cross for helpful discussions. Many users of FEFFIT have helped to make it more robust and useful, especially Anatoly Frenkel, Boyan Boyanov, Chuck Bouldin, Daniel Haskel and Shelly Kelly. Thanks to Vince Harris and Julie Cross for the data used as the example in this paper.

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JOURNAL OF
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ISSN: 1600-5775

Volume 8| Part 2| March 2001| Pages 96-100

doi:10.1107/S0909049500016290