3.1. Background

While analysis of Bragg diffraction allows us to determine the average crystal structure, in disordered materials, or in ordered nano-crystalline materials, a significant component of diffuse scattering is often ignored or folded into a background correction in the Rietveld methodology. For determination of structural information in disordered or amorphous materials, full-profile fitting of the pair distribution function (PDF) has proven a powerful alternative technique, and is routinely performed using data collected at ambient P (Egami & Billinge, 1994; Petkov et al., 2002; Billinge, 2004; Proffen et al., 1999). The atomic PDF, G(r) is defined as

where ρ(r) and ρ₀ are the local and average atomic number densities, respectively, and r is the radial distance. G(r) is then the probability of finding an atom at a distance r from a reference atom and so is related to the atomic structure. G(r) is derived by Fourier transforming the experimentally observed total structure factor (Wasada, 1980), S(Q),

where Q is the magnitude of the wavevector [Q = 4πsin(θ)/λ]. The above equation implies that the total scattering, and not just the Bragg scattering, contributes to G(r). Both the long-range order, giving rise to sharp Bragg reflections in the diffraction patterns of crystalline materials, and the short-range order, giving rise to diffuse scattering, are reflected in the PDF. Further, the PDF can serve as a basis for structure refinement and, perhaps, structure determination (Petkov et al., 1999, 2002).

Because of the nature of the scattering from nano-crystalline materials, particularly the lack of sharp Bragg diffraction features, the discrimination between closely related structure models, especially from the compromised data available from high-P devices, may be more problematic. Other considerations include (i) the importance of separating out the coherent scattering from incoherent scattering contributions; diamonds, of course, if they are in the beam, will contribute considerable incoherent Compton scattering; and (ii) the need to collect data to as high a value of Q as possible to avoid Fourier termination errors which will show up as ripples in the PDF. Once derived, a properly normalized PDF can be used in a `Rietveld-like' refinement. A model structure is constructed and the PDF derived from this model. Atomic positions, displacement parameters, occupancies and other model-dependent parameters are then varied to improve the fit between observed and calculated PDF (Egami & Billinge, 2003).

The PDF, which is the measure of the probability of finding atom pairs separated by distance r, is also a means of measuring the primary particle size for nano-particles (Fig. 1). For highly crystalline materials the largest distance observable is limited by the instrument resolution, and for crystalline materials such as bulk FeS (Fig. 1) this extends beyond 50 Å. For nano-crystalline materials, such as the freshly precipitated FeS sample (Fig. 1), the PDF is severely attenuated above about 4 nm. This is because, beyond 4 nm for the FeS particles, only intra-particle distances, those <4 nm, would be observed. The behavior of nano-materials under P is of topical interest (Lipinska-Kalita et al., 2003; Chen et al., 2002; Wang & Saxena, 2002; Wang et al., 2001a,b) and being able to determine the primary particle size, at room and at high P, is clearly a first step to characterization.

Figure 1 Comparison of Q[S(Q) − 1], derived from scattering data collected on an imaging plate (Fig. 2) using 100 keV X-rays at beamline 1-ID, and G(r) plotted out to 50 Å to illustrate the degree of attenuation owing to the range of structural coherence, i.e. fundamental particle size, of a nano-crystalline sample of FeS (nano-FeS) and a crystalline sample of FeS (bulk FeS). Determination of fundamental particle size of the crystalline FeS is limited by the instrument resolution, which does not extend beyond ∼14 nm, but clearly the correlations in G(r) for nano-FeS are severely attenuated after about 4 nm.

3.2. Deriving PDF from high-P data for heavy scatterers

Acquiring scattering data suitable for PDF analysis at high P has primarily required the use of large-volume apparatus as opposed to the DAC. Both high-P cells are subject to considerable parasitic background contributions and narrow 2θ scattering windows, which introduce significant noise to the structure function, S(Q), and final PDF [G(r)]. Increasing the 2θ range of data collection and/or scattering vector (Q) by increasing the energy of incident radiation improves data quality and eliminates the need for PDF reconstruction, such as Kaplow-type iterative procedures, which force the distribution function to expected values (Shen et al., 2003; Eggert et al., 2002), introducing experimenter bias.

In an initial trial experiment we chose an `ideal' case to test the viability of using high-energy X-rays to perform quantitative high-pressure pair distribution function (QHP-PDF) analysis: gold with a particle size of 50–100 nm, which gives relatively sharp diffraction features (Fig. 2). The purpose of this initial study was to explore the viability of corrections to the collected diffraction data and the suitability of these data for deriving PDFs for full fitting of structure models. The structure model in this case can be fitted with both Rietveld and with PDF methodologies and so direct comparison can be made of the results. We collected high-energy monochromatic X-ray scattering below the Au edge [79.9562 (5) keV; 0.15507 (3) Å] at the 1-ID beamline of the Advanced Photon Source (APS) at Argonne National Laboratory with 50 µm × 50 µm beam defined by slits. The sample, contained in a standard Merril–Bassett-type DAC, was compressed hydrostatically using an alcohol pressure medium of methanol:ethanol (4:1). Pressure was determined by the ruby fluorescence technique.

Figure 2 Typical exposure on a MAR345 imaging plate illustrating the single-crystal diamond spots alongside powder diffraction from gold held at 8.5 GPa in a DAC. These spots must be carefully masked prior to data integration.

For our initial measurements we find that scattering to 20 Å⁻¹ (Petkov et al., 1999) is sufficient for high-quality PDFs of crystalline gold (Martin et al., 2005). Full details of our experimental set-up are reported elsewhere (Martin et al., 2005) but certain aspects are worth repeating here, since the possibility of using nano-phased materials for QHP-PDF holds great promise. In principle the protocols used for the initial study are straightforward and many synchrotron beamlines have the necessary set-up to perform these measurements.

Diffraction patterns were collected using a MAR345 imaging-plate detector. Data treatment included subtraction of background, determined from exposures at ambient P without the sample in position, and exclusion of single-crystal diamond spots, followed by integration with Fit2D (Hammersley et al., 1996). To avoid saturation of the detector on any single exposure, and to obtain optimal counting statistics, data were obtained by averaging many short exposures. Typically, data were collected for ten 5 s exposures, which were averaged to attain optimum counting statistics. Integrated data were processed to PDFs using the program PDFgetX2 (Qiu et al., 2004), where standard corrections as well as those unique to the image-plate geometry were applied (Chupas et al., 2003). Full profile fitting of the PDF was performed using program PDFFIT (Proffen & Billinge, 1999), while the program EXPGUI (Toby, 2001) for GSAS (Larson & Von Dreele, 2000) was used for Rietveld analysis of Bragg diffraction, in order to compare refined model parameters, which are discussed fully in our previous work (Martin et al., 2005).

Several potential pitfalls are avoided by looking at a heavy scatterer such as gold in this initial trial (Martin et al., 2005). The coherent scattering contributions from the methanol:ethanol (4:1) pressure-transmitting medium at 80 keV are small compared with gold. In addition, significantly less pressure-transmitting medium is in the beam than Au sample. The correlations from the alcohol pressure medium must exist and will become more obvious when light elements are used. This will require some combination of samples being loaded in He, elimination of the pressure medium, perhaps along with heating of the sample to eliminate deviatoric stress, and the collection and proper normalization of blanks for subtraction of the pressure-medium contribution. More problematic are contributions from the incoherent scattering of diamond and the severe limitations placed on the brilliance of the beam by using slits rather than an appropriate focusing optic.

3.3. Recent modifications to the experimental set-up

While the protocol described above works well for heavy scatterers, for lighter scatterers it is essential to properly correct for background to remove long-wavelength errors in S(Q), which will Fourier transform into physically meaningless peaks in the low-r (Å) region of the PDF. Tests of the validity of our background correction included comparison of PDFs obtained from gold in a capillary versus gold in the DAC at ambient P; we found that the difference in PDF between the capillary and DAC is minimal. In the case of heavy scatterers such as gold, we conclude that the background correction is indeed valid and that the data obtained from scattering from crystalline gold are of sufficient quality to allow the derivation of quantitative and well normalized PDFs.

The significant contribution to the background from diamond will need to be addressed (Martin et al., 2005) for studies of glasses, melts and light elements, since in these cases Compton scattering can overwhelm the signal of interest. One solution is to maximize sample size while not compromising P capabilities and, in cases where P > 35 GPa is required, larger-volume gem anvil cells are currently under development for neutron sources (Xu et al., 2002). These new devices allow a large sample volume to be taken to pressures above 35 GPa. In those cases where the sample is sufficiently large to allow tight collimation, the problem of Compton and parasitic scattering from high-P cell components is greatly reduced.

Another alternative that will increase the signal-to-noise discrimination is to decrease the inelastic signal by removing some of the diamond from the beam path using perforated diamond anvils (Dadashev et al., 2001) with the geometry shown in Fig. 3. In this case, a conical hole of about 0.5 mm maximum and 80 µm minimum diameter is perforated into the diamond to within 200 µm of the 350 µm-culet. A similar hole is made into the diamond located towards the detector and a miniature anvil set upon it. Providing a beam can be introduced down the hole, in the direction of the arrow in Fig. 3, Compton scattering can be significantly reduced. It is important in this case to focus the incident beam rather than to use beam slits to define the beam size. This maximizes the X-ray flux on the sample. Beamline optics at beamline 1-ID at the APS are well matched to the studies of nano-crystalline and glassy materials at high PT. Focused X-rays with energies in the 80–120 keV range provide data to Q > 20 Å⁻¹ with standard imaging-plate geometries, while minimizing background from the DAC.

Figure 3 A schematic drawing of a DAC with perforated anvils. DBP: diamond backing plate made of ∼0.25 carat diamond. Upper conical hole cut to accommodate diameter of incoming beam. PPA: partial perforated anvil made of 0.25 carat diamond with a conical hole. MA: miniature anvil made of ∼0.05 carat diamond.

The high-energy X-rays at beamline 1-ID are delivered by a bent double-Laue monochromator followed by vertically focusing refractive lenses. The liquid-nitrogen-cooled monochromator (Shastri et al., 2002) consists of two bent Si(111) Laue crystals arranged to sequential Rowland conditions and provides high flux in a beam of preserved source brilliance (divergence and size). The focusing refractive lenses, placed immediately after the monochromator, are of either the cylindrical aluminium (Shastri, 2004) or saw-tooth silicon (Cederstrom et al., 2002) types, giving line foci of 16–80 µm in vertical size at the end-station, with flux density gains in the range 6–20. A comparison of data collected with and without the perforated diamond anvils and with the focusing optic at 1-ID in place is shown in Fig. 4.

Figure 4 Diagrams showing Q[S(Q) − 1] for nano-CeO2 in (top) a cell fitted with perforated diamonds (Fig. 3) and (bottom) a standard diamond anvil cell. There is a dramatic decrease in the contribution to the overall scattering from diamonds in the perforated cell and this leads to a much better signal-to-noise discrimination at high Q, an important factor in deriving better resolved real-space correlation functions containing fewer `ripples' owing to Fourier termination errors.