research papers

J. Synchrotron Rad. (2023). 30, 327–339 https://doi.org/10.1107/S1600577522011614 327

Received 29 April 2022

Accepted 2 December 2022

Edited by A. Bergamaschi, Paul Scherrer Institut,

Switzerland

Keywords: pair distribution function; powder

X-ray diffraction; Mythen-II detector; total

scattering.

Supporting information: this article has

supporting information at journals.iucr.org/s

Total scattering measurements at the Australian
Synchrotron Powder Diffraction beamline:
capabilities and limitations

Anita M. D’Angelo,a* Helen E. A. Brand,a Valerie D. Mitchell,a Jessica L. Hamilton,a

Daniel Oldfield,b Amelia C. Y. Liuc and Qinfen Gua*

aAustralian Synchrotron, Australian Nuclear Science and Technology Organisation (ANSTO), 800 Blackburn Road,

Clayton, Victoria 3168, Australia, bAustralian Nuclear Science and Technology Organisation (ANSTO), New Illawarra

Road, Lucas Heights, New South Wales 2234, Australia, and cSchool of Physics and Astronomy, Monash University,

Wellington Road, Clayton, Victoria 3800, Australia. *Correspondence e-mail: anitad@ansto.gov.au,

qinfeng@ansto.gov.au

This study describes the capabilities and limitations of carrying out total

scattering experiments on the Powder Diffraction (PD) beamline at the

Australian Synchrotron, ANSTO. A maximum instrument momentum transfer

of 19 �1 can be achieved if the data are collected at 21 keV. The results detail

how the pair distribution function (PDF) is affected by Qmax, absorption and

counting time duration at the PD beamline, and refined structural parameters

exemplify how the PDF is affected by these parameters. There are

considerations when performing total scattering experiments at the PD

beamline, including (1) samples need to be stable during data collection,

(2) highly absorbing samples with a �R > 1 always require dilution and (3) only

correlation length differences >0.35 Å may be resolved. A case study comparing

the PDF atom–atom correlation lengths with EXAFS-derived radial distances of

Ni and Pt nanocrystals is also presented, which shows good agreement between

the two techniques. The results here can be used as a guide for researchers

considering total scattering experiments at the PD beamline or similarly setup

beamlines.

1. Introduction

In a typical powder diffraction experiment from a crystalline

specimen, where only the Bragg reflections are studied, only

information on the average long-range order of atomic

structures is available. However, further insight into the

functional properties may be obtained through understanding

the local structure by analysing both the sharp Bragg and the

diffuse scattering from disorder via total scattering analysis.

Both Bragg and diffuse scattering are considered in total

scattering experiments and the pair distribution function

(PDF) is obtained through Fourier transform of the total

scattering data.

A PDF shows the probability of finding an atom at distance

r from a specified atom. The technique has applications for

nanoparticles, disordered materials, non-periodic materials

such as amorphous glasses, as well as systems where the local

structure is different to the average structure. PDF measure-

ments can provide information on a short- and medium-length

scale and are complementary to other techniques such as

extended X-ray absorption fine structure (EXAFS). EXAFS

provides local information up to the first three atomic shells or

�6 Å as the signal attenuates dramatically when the distance

between the neighbouring and absorbing atom increases.

In contrast, a PDF can provide information beyond 1000 Å

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depending on the instrument resolution in reciprocal space.

EXAFS is used to target the local structure of a specific

element whereas PDF provides local structure information

from all atom pairs. However, this means pairs close to each

other can be hard to resolve using PDF. Structural details that

can be examined include (1) the direct atom pair separation

length from peak positions, (2) the degree of disorder of the

atom pair from the peak width, (3) static and dynamic

disorder, (4) the phases present in mixed-element systems

using differential PDFs, (5) details about specific atom–atom

correlations via partial PDFs and (6) coordination number

from the integrated peak intensity if the data are on an

absolute scale (Takeshi & Billinge, 2012).

High counting statistics are needed as both the Bragg and

the diffuse scattering contribute to the PDF. The atomic X-ray

form factor decreases with increasing Q, which contributes to

a decrease in Bragg peak intensity and non-uniform counting

statistics. The S(Q) is obtained by subtracting self-scattering

and normalizing the coherent scattering intensity per atom

Icoh(Q), according to equation (1) where Q is the magnitude of

the scattering vector, ci is the atomic concentration and fi is the

X-ray form factor for atom type i (Farrow & Billinge, 2009;

Billinge & Farrow, 2013). The reduced structure function F(Q)

is determined from S(Q). A Fourier transform is applied to the

normalized total scattering data to generate the reduced PDF

G(r), where �0 is the number density, g(r) is the PDF, Q is the

magnitude of the wavevector transfer, S(Q) is the structure

function and r is the distance between two atoms in the sample

[equation (2)] (Farrow & Billinge, 2009). Note there are many

different total scattering correlation functions, of which their

definition also varies (Keen, 2001),

SðQÞ ¼ 1þ
IcohðQÞ �

P
ci f iðQÞ
�� ��2P

ci f iðQÞ
�� ��2 ; ð1Þ

GðrÞ ¼ 4��0 gðrÞ � 1½ � ¼
2

�

� �Z Qmax

Qmin

Q½SðQÞ � 1� sinðQrÞ dQ:

ð2Þ

High-energy X-rays are generally used in PDF experiments to

increase the momentum transfer and real space resolution. For

example, experiments have been carried out using a resolution

of 0.126 Å for 28-ID-1 at the National Synchrotron Light

Source II, and 0.0898 Å for the General Materials Diffract-

ometer (GEM) at ISIS Neutron Source of Rutherford

Appleton Laboratory (Frandsen et al., 2019). A disadvantage

of lower real space resolution is that correlation lengths that

are similar cannot be resolved. This is because the limits of the

G(r) function are determined by the Q-range. As an example,

the Zn—Se and Zn—Te bonds in ZnSe0.5Te0.5 cannot be

distinguished at Qmax = 17 �1 as the bond length difference is

0.14 Å, whereas they are clearly visible at Qmax = 40 Å�1

(Proffen et al., 2003). A high Q-range can typically be achieved

in two ways: (1) increasing the beam energy if using a flat-

panel 2D detector, or (2) increasing the 2� angle using a point

or 1D detector if the maximum energy is limited. PDFs can

also be generated using neutron or electron sources. PDFs

generated from electrons (ePDF) allow for smaller samples to

be analysed and data with higher spatial resolution can be

obtained (McBride & Cockayne, 2003, 2007). Neutron PDF

experiments are commonly carried out at spallation sources

including ORNL, ISIS, J-PARC and the European Spallation

Source. Reactors such as D4 at Institut Laue-Langevin can

also generate short-wavelength neutrons (i.e. 0.35 Å and

covering 1.5 to 140� 2�) with a hot source that makes them

suitable for total scattering studies (Fischer et al., 2002).

Synchrotron hard X-ray sources are generally preferred

over laboratory X-ray sources due to the higher energy and

higher flux available. The energy used on dedicated PDF

beamlines is typically >60 keV, i.e. 76.6 keV at I15-1 at

Diamond Light Source, 86.7 keV at 11-ID-B at the Advanced

Photon Source (APS) and up to 117 keV at 28-ID-1 at Brook-

haven National Laboratory. However, reasonable values of

Qmax can be achieved using lower-energy X-rays such as

those generated in the laboratory using Mo K� (17.4 keV)

(Rantanen et al., 2019; Galliez et al., 2014) and Ag K�
(22.1 keV) (Wu et al., 2018; Bueken et al., 2017) radiation.

Dykhne et al. (2011) detailed a comparison of PDF data

generated from laboratory X-ray sources for pharmaceutical

applications. Furthermore, PDF studies have also been carried

out on lower-energy beamlines such as DanMAX at MAX IV

with a maximum energy of 35 keV. PDF studies at the X-ray

Diffraction and Spectroscopy (XDS) beamline at the Brazilian

Synchrotron Light Laboratory (LNLS) have been carried out

at 20 keV with Qmax = 20 �1 using a Mythen-II detector by

collecting between 1� and 165� 2�, and the results were

compared with PDF studies carried out at the 11-ID-B PDF

beamline at the APS (Saleta et al., 2017). In their work the

authors reported that XDS can obtain high-quality PDF data

and is preferential to study r regions >30 Å in comparison

with the APS. This was attributed to a smaller dampening

factor calculated from XDS compared with APS. Despite this,

studies carried out at lower energies may also only report

qualitative results due to the limited resolution achieved.

The Australian Synchrotron is a third-generation light

source that operates at 3 GeV and 200 mA during user

operations. The PD beamline is optimized to carry out in situ

studies in a broad range of fields including energy, condensed

matter science, materials engineering and environmental

science. It is located on a bending magnet with a magnetic field

of 1.3 Tand a critical energy of 7.78 keV. After several years of

user operations, the PD beamline optics were upgraded and

simplified to better meet the needs of the user community.

In the original beamline design the double-crystal mono-

chromator (DCM) had both a flat Si(111) and an Si(311) flat/

sagittally bent crystal pair. The mirrors were also designed

with multiple stripes for optimal reflectivity over the full

energy range of the beamline (4–30 keV). The recent upgrade

removed the Si(311) crystal pair and redesigned the crystal

mounting for added stability as well as upgrading the mirrors

to add horizontal focusing. The vertical collimating mirror

(VCM) and vertically focusing mirror (VFM) were replaced

with a single-stripe Rh-coated flat and toroid mirror that

provided additional flux through the ability to horizontally

research papers

328 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO J. Synchrotron Rad. (2023). 30, 327–339

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focus the beam to �0.8 mm � 0.6 mm in the first endstation.

The useable range of energies on the beamline is now 8–

22 keV as the reflectivity of the Rh mirror coating drops off

substantially above 22 keV.

The PD beamline consistently receives requests to carry out

total scattering experiments for various materials including

battery electrodes, piezoelectrics and coordination framework

materials. Early in user operations, studies were carried out

by Haverkamp & Wallwork (2009) to assess the feasibly of

PDF measurements at the PD beamline using the Mythen-II

detector at 21 keV. In this work the need for a wide Q-range,

fluorescence elimination and removal of the detector gaps

between the detector modules (as per standard beamline

procedure) were highlighted. The Mythen-II can achieve

Qmax = 40 �1 if data are measured over 155� 2� at 40 keV

(Bergamaschi et al., 2010). However, it is important to note

that the Mythen-II detector efficiency at 5–10 keV is 85% and

decreases to �25% at 20 keV for a 300 mm silicon wafer

thickness that is used at the PD beamline. The efficiency could

be improved by increasing the thickness of the silicon wafer.

The Mythen-II has been used in PDF studies at the Materials

Science Beamline (Swiss Light Source) with Qmax = 23 �1

(Černý et al., 2009) and Qmax = 28 Å�1 (Saha et al., 2021).

These recent beamline upgrades have prompted us to

provide an update of the current PDF capabilities at the PD

beamline. The aim of this study was to benchmark total scat-

tering measurements carried out at the beamline. It demon-

strates what can be offered to our user community through

exploration of variations in Qmax, absorption and counting

time. A case study comparing the PDF atom–atom correlation

lengths with EXAFS-derived radial distances is also

presented.

2. Experimental

2.1. Materials

Ni powder (99.8%), Cu powder (10 mm spheroidal, 99%)

and SiO2 nanopowder (10–20 nm, 99.5%) were purchased

from Sigma–Aldrich. Ni, NiPt (1:1), dealloyed NiPt (1:1) and

Pt metal nanoparticles (20 wt.%) supported on carbon were

synthesized via the methods described by Wang et al. (2018).

2.2. Powder diffraction

Diffraction data were collected at the PD beamline at the

Australian Synchrotron, ANSTO, using a Mythen-II detector

over 124� 2� using four detector positions (Bergamaschi et al.,

2010). Samples were packed into 0.3 mm borosilicate capil-

laries and rotated during data collection. The Mythen-II at

the PD beamline has 16 modules that cover 80� 2� and each

module has an angular range of 4.83� with a physical separa-

tions of 0.17�. Patterns were obtained at starting angles of

2� 2� (position 1), 2.5� 2� (position 2), 51.5� 2� (position 3)

and 52� 2� (position 4). The in-house-developed program

PDViPeR was used to normalize and splice the four patterns

and remove the gaps in the data. The wavelength, zero error

and instrument contribution to the peak profile were deter-

mined using the line position and line shape standard NIST

LaB6 660b. The refined wavelength was 0.58907 (1) Å for the

nanoparticle and Cu sample collections, and 0.58926 (1) Å for

the Ni powder.

The instrument momentum transfer achievable by

measuring 124� 2� was 19 �1. An empty capillary was used

as the background for the Ni and Cu powder. An SiO2-filled

capillary was used for the Cu mixed with SiO2 samples. A

capillary filled with carbon was used as the background for the

metal nanoparticles so a PDF of the metal nanocrystal without

a carbon contribution could be extracted. xPDFsuite was used

to generate the S(Q), F(Q) and G(r) functions (Yang et al.,

2014) using Qmax = 18 �1. This software uses an ad hoc

approach to correct and normalize the measured data before

transformation to the PDF (Juhás et al., 2013). The back-

ground scale was optimized to ensure that S(Q) oscillates

around 1. Qmin = 0.5 �1, rmin = 0.01 and rstep = 0.01 were used

for all data. Qbroad = 0.0017 (1) and Qdamp = 0.0035 (1) were

determined from refining a NIST Si 640d standard in a 0.3 mm

capillary between 1 Å and 2000 Å in TOPAS (version 6;

Coelho, 2018a,b). Rietveld refinement and modelling of PDF

patterns were carried out in TOPAS (version 6), and PDFs for

NiPt, dealloyed NiPt and Pt were modelled up to 15 Å using a

numerical spherical shape function (Usher et al., 2018).

2.3. Transmission electron microscopy

Transmission electron microscopy (TEM) images for Ni

were obtained on a JEOL 2200FS TEM at 200 kV. Images for

the NiPt, dealloyed NitPt and Pt nanoparticles were obtained

using a double-corrected FEI Titan 3 FEGTEM operated at

300 kV in scanning transmission electron microscopy (STEM)

mode with a probe convergence semi-angle of 15 mrad.

Bright-field (BF) and high-angle annular dark-field (HAADF)

images were collected. Samples were prepared by adding a

small quantity of the powder to ethanol and dropping 3 ml of

the solution onto a Cu holey carbon Quantifoil grid then

allowing to dry. Particle counting was carried out using ImageJ

1.53k via watershed image processing of the HAADF images.

The average diameter of the nanoparticles was determined by

fitting a Gaussian distribution to a scatter plot of the binned

counts plotted as a function of particle size.

2.4. X-ray absorption spectroscopy

Samples were measured using X-ray absorption spectro-

scopy (XAS) at the XAS beamline at the Australian

Synchrotron, ANSTO. XAS spectra were recorded at the

platinum L3- and nickel K-absorption edges in fluorescence

mode at 4 K in a helium atmosphere using a 100-element

solid-state HP-Ge detector (Canberra/Mirion, France). The

excitation energy was selected using an Si(111) DCM, which

was calibrated at the Pt L3- and Ni K-absorption edges using

inline metal foils (the first maximum of the first derivative was

at 11562.76 eV and 8331.49 eV for Pt and Ni, respectively).

The samples were diluted to 1000 p.p.m. in cellulose and

pressed into 7 mm pellets which were then loaded into

Perspex holders and sealed with Kapton tape. The corre-

research papers

J. Synchrotron Rad. (2023). 30, 327–339 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO 329

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sponding reference foils for Pt and Ni were analysed simul-

taneously with the appropriate samples. X-ray absorption fine

structure (XAFS) scans were performed with a count time of

2 s for each energy step in the pre-edge and X-ray absorption

near-edge spectroscopy (XANES) region, with 10 eV steps in

the pre-edge region of the XAS spectra, and 0.25 eV steps

in the XANES region. In the EXAFS region, spectra were

collected in steps of 0.035k to a maximum of 20k, with count

time increasing linearly from 2 s up to 10 s at the end of the

EXAFS range. Data were pre-processed using the in-house

program Sakura (Kappen et al., 2015) and the Demeter

package for normalization and EXAFS fitting (Ravel &

Newville, 2005). The R-factors of the EXAFS fits obtained and

presented in Section 3.5.2 were 0.005 and 0.004 for Ni and Pt,

respectively.

3. Results and discussion

3.1. Instrument characterization

The effect of the instrumental resolution on the PDF was

investigated using NIST Si 640d with a certified lattice para-

meter of 5.43123 (8) Å. Peaks dampen at high G(r) owing to

changes in the effective angular resolution (�Q/Q) across Q

in reciprocal space. The amplitude of the PDF peaks will

dampen less at high r for high reciprocal space resolution

instruments such as the PD beamline, which is optimized for

high-resolution studies with an energy resolution of �E/E =

7.4 � 10�4 at 15 keV. The Mythen-II detector also provides an

intrinsic angular resolution up to 0.004� with a 50 mm strip

pitch (Haverkamp & Wallwork, 2009; Gozzo et al., 2010). The

intrinsic angular resolution is greater for the PD beamline

compared with those beamlines that are optimized for PDF

studies because of the beamline optics and the use of the

Mythen-II instead of a 2D detector,

SðrÞ ¼ exp �
1

2
r 2

�Q

2:35482

� �2
� �

: ð3Þ

The Gaussian dampening envelope was determined by equa-

tion (3), where S(r) is the r-dependent scale factor, �Q is the

width of the Gaussian determined by fitting the PDF (Qdamp)

to 2000 Å and r is the distance between two atoms in the

sample. Fig. S2 of the supporting information shows the

r-dependent scale factor up to 3000 Å. The degree of

dampening is due to the Q resolution of the instrument and is

advantageous when information of the medium-range atomic

structure is required. For example, through modelling the

crystalline contribution in the 40–60 Å region, correlations

from nano-crystalline components up to 40 Å were extracted

from cement data measured on the 11-ID-B beamline at the

APS (White et al., 2015). Work by Saleta et al. (2017)

compared PDF data obtained on a Mythen detector at XDS at

the LNLS with data obtained on 11-ID-B at the APS and

showed that the PDF peaks attenuate quicker in the APS data.

The LNLS PDF data were considered higher quality at higher

r whereas the APS data were considered higher quality at

lower r. The main advantage of the total scattering setup at the

PD beamline is the lower dampening compared with typical

high-energy PDF beamlines.

To investigate the effect of sample volume on the effective

angular resolution in both real and reciprocal space, NIST

Si 640d data were collected in both a 0.3 mm and a 1 mm

capillary. Individual peaks were fitted with a pseudo–Voight

and the full width at half-maximum (FWHM) determined. As

expected, Fig. S3(a) shows that the FWHM increases as 2�
increases and the FWHM is larger for a 1 mm capillary

compared with a 0.3 mm capillary. The FWHM of the Si(111)

reflection was 0.0072 (1)� measured in a 0.3 mm capillary and

0.0142 (1)� in a 1 mm capillary. The effective angular resolu-

tion is lower for a larger sample volume as scattering extends

over a greater angular range. The broadening contribution

from a 0.3 mm capillary can span 0.006� versus 0.019� for a

1 mm capillary at a 762 mm sample-to-detector distance

(Bergamaschi et al., 2010; Gozzo et al., 2010). Work by Scarlett

et al. (2011) has also shown sample displacement artefacts in

the diffraction data of minerals nucleating on the walls of

1 mm capillaries as the peaks shift from their ideal positions to

higher and lower angles. These authors went on to formalize

this observation in a sample displacement correction for

this geometry.

PDFs were generated from the Si collected in a 0.3 mm and

1 mm capillary to determine the effect that capillary size and

effective angular resolution have on the peak FWHM across r.

The peak width is convoluted with an instrument broadening

term in real space and can be described using equation (4) if

the Q-dependent broadening is linear, where �0 is the FWHM

of a peak, � is the Gaussian broadening term (Qbroad) and �q is

the FWHM of a peak convoluted with the broadening term

(Thorpe et al., 2002). The �q of the first peak at 2.35 Å was

used to determine �0 and establish the FWHM as a function of

r from equation (4). Fig. S3(b) shows that the FWHM

increases as r increases and is larger for the 1 mm capillary. At

low r there is only a small difference in the peak widths

(0.04 Å at r = 50 Å) between the capillary sizes and this

difference increases due to peak broadening effects across Q,

�2
q ¼ �

2
0 þ �

2r 2: ð4Þ

In this work, the lattice parameters, atomic displacement

parameters (ADPs) and scale factor were calculated in ‘box-

car’ refinements using 10 Å windows and moving the centre of

the ‘box’ by 5 Å. The dampening and broadening parameters

were set to zero as this allowed us to determine how these

parameters change across r. Lattice parameters were deter-

mined with and without correcting for instrumental effects on

the peak profile and zero offset. In both, the lattice parameter

was consistent across r [Fig. 1(a)]. The lattice parameters

obtained by fitting the PDF without corrections were lower

than the value of 5.4311 (1) Å from the Rietveld refinement,

although they were comparable. Fig. S1 shows the fit to the

NIST Si 640d standard in reciprocal space. The lattice para-

meter was 5.4302 (1) Å by refining between 1 Å and 100 Å,

and at low (5 Å) and high (200 Å) r was �0.02% or 0.001 Å

lower than the lattice parameter calculated from the Rietveld

research papers

330 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO J. Synchrotron Rad. (2023). 30, 327–339

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refinement of the Bragg peaks. This difference between the

lattice parameter calculated from the PDF and Bragg peaks

can be attributed to a zero offset and peak asymmetry in

reciprocal space. The PDF was then generated and corrected

for the peak profile described by fundamental parameters and

zero offset using TOPAS (version 7; Coelho, 2020, 2021). The

corrected lattice parameter was 5.4307 (1) Å by refining

between 1 Å and 100 Å and at low (5 Å) and high (200 Å) r

was <0.01% or <0.001 Å lower than the lattice parameter

calculated from Rietveld refinement of the Bragg peaks. The

Bragg peaks in the data from the PD beamline can have peak

asymmetry that attributed to to axial divergence that can be

modelled using a circles function via a fundamental para-

meters approach (Cheary & Coelho, 1992). In both real and

reciprocal space, the peak position is determined from a delta

function convoluted with line shape. The line shape has

instrument and sample contributions. If an asymmetric line

shape is not considered in the model then the intensity centre

position can be different from the ‘ideal’ peak position

obtained from the delta function only (Jeong et al., 2005).

Larger differences between the lattice parameter calculated

from real and reciprocal space data can then be observed, as

shown in this work. Asymmetric peak shapes can also cause r-

dependent peak shifts, a reduction in the ability to fit peaks

at high r (shown by a higher Rwp) and changes to dampening

behaviour (Olds et al., 2018; Jeong et al., 2005). The PDF-

derived lattice parameter in this work shows good agreement

with the Rietveld-derived lattice parameter once the data

were corrected for peak profile and zero offset effects.

Consequently, PDFs should be corrected for instrumental

effects to minimize unwanted effects in the PDF.

There was an increase in the ADP across r showing an

increase in peak width attributed to r-dependent peak-

broadening [Fig. 1(b)]. A decrease in scale factor at high r may

also indicate dampening of the peaks (Qiu et al., 2004)

[Fig. S4(a)]. The ADP was 0.567 (2) Å2 determined from

Rietveld refinement and comparable to the 0.553 (1) Å2 from

the PDF by refining the data between 1 Å and 100 Å

[Fig. 1(b)]. Fig. S4(b) also shows the change in Rwp across r.

Both dampening and broadening of the peaks due to the

instrument can be accounted for using a standard and the

values determined applied to samples during analysis.

3.2. Effect of Q-range

An energy of 21 keV is typically used for measurements at

the PD beamline as flux dops off significantly above 22 keV.

Ideally, all samples are measured at the highest available

energy to increase the momentum transfer, i.e. to obtain a high

Qmax and low Qmin. The ability to resolve two peaks in a PDF

is primarily determined by the Q range.

Qmin = 0.37 Å�1 (d ’ 17 Å) can be reached if the data are

measured from 2� 2� at 21 keV. Angles lower than 2� 2�
cannot be accessed if also measuring to the higher angles

needed for total scattering experiments, as scattering from our

current beam stop is observed at higher angles (typically >60�

2�). However, for reciprocal space measurements, data from

1� 2� (d ’ 33 Å) are routinely collected for materials with

large unit cells by positioning the beam stop to reduce the

small angle scattering and not cut the background intensity.

The PD beamline is considering modifying the beam stop to

reach lower angles while also avoiding backscatter. There is a

trade-off between accessing low and high angles in the

beamline setup with our current beam stop, so for total scat-

tering experiments Qmin = 0.5 �1 should be used to generate

the PDFs.

Measuring samples at an energy lower than 21 keV was

considered in this work if samples contain elements that will

have significant fluorescence when measured at 21 keV. The

Mythen-II detector is sensitive to fluorescence, so the contri-

bution of a fluorescence background to the measured data is

minimized if the energy selected is below the absorption edge

or greater than 6 keV above the absorption edge (Berga-

maschi et al., 2010). However, using a lower energy will

obviously reduce the achievable Qmax and decrease the Qmax

used, and hence cause an increase in peak-broadening,

research papers

J. Synchrotron Rad. (2023). 30, 327–339 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO 331

Figure 1
Data obtained from NIST Si 640d show (a) the PDF- and Bragg peak-
derived lattice parameters are comparable and the PDF-derived value
does not significantly change across r, where the circles are the lattice
parameters corrected for peak shape and zero offset, and the triangles are
the lattice parameter without correcting for peak shape and zero offset;
and (b) the ADP increases across r due to peak broadening. The blue
dashed lines indicate the lattice parameter and ADP obtained from
Rietveld refinement.

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decrease in peak height and increase in the intensity of

termination ripples (Qiu et al., 2004).

The extent to which the loss in real space resolution and

variation in the calculated structural parameters increases

was investigated for experiments where lower energies are

considered. To investigate this, PDFs of an Ni powder sample

were generated with Qmax = 14 �1, 15 �1, 16 �1, 17 �1

and 18 �1. The instrument parameters were also refined for

each Qmax. Fig. 2(a) shows that there is little to no observable

difference between PDFs with Qmax = 17 �1 and 18 �1.

There are three peaks between 7.7 Å and 8.7 Å in both of

these PDFs, and the loss in resolution is obvious when Qmax �

16 �1 as there are only two peaks visible in this region. The

loss in resolution is also highlighted by the peak at 3.5 Å for

Qmax = 14 �1 where the peak and termination ripples cannot

be distinguished from each other. Resolution in real space can

be estimated by �r = 2�/Qmax (Petkov, 2012) so the resolution

achieved using Qmax = 18 Å�1 is 0.35 Å, and for Qmax = 16 Å�1

it is 0.39 Å. This shows that only differences between corre-

lation lengths that are >0.35 Å can be resolved at the PD

beamline.

Changes in the lattice parameter and ADP were quantita-

tively evaluated by fitting the PDF data between r = 1 Å and

r = 30 Å. The refined parameters are presented in Table S1.

The lattice parameters for Qmax = 14–18 Å�1 are comparable

and the ADPs increased when Qmax decreased. Peaks appear

visibly broader at 2.5 Šand 4.3 Šfor Qmax = 14 �1

compared with Qmax = 18 �1 [Fig. 2(b)]. Larger ADPs are

obtained from broader peaks as they indicate atomic motion

or static disorder. Correlations in the PDF broaden due to

these effects as well as termination of the function at Qmax.

This is due to convolution of G(r) with a broadening function,

sin(Qmax�r)/�r.

A low Qmax resulted in the highest discrepancy between the

ADPs of an experimental and a calculated PDF (Toby &

Egami, 1992). Termination broadening can be reduced and is

minimal if a high enough Qmax is used. Toby & Egami (1992)

report that the errors in a PDF are minimal when Qmax >

30 �1. Qiu et al. (2004) showed from neutron PDF data of Pb

that the peak intensity of the next-nearest neighbour at 3.48 Å

does not increase further above Qmax = 37 �1 as the reso-

lution is no longer measurement-limited. However, it is

important to note that this is material-dependent. Conse-

quently, the ADPs determined here are larger at lower Qmax

due to peak-broadening from termination of the PDF.

Although PDFs can be generated with a lower Qmax, the

structural parameters for some materials may not be able to

be determined owing to decreasing accuracy of the calculated

parameters. Only qualitative data and relative changes

between samples may be useable in this case. Users of the PD

beamline will need to consider whether the achievable real

space resolution is adequate to resolve the correlations of

interest in their materials.

3.3. Absorption and the PDF

X-ray absorption effects are not generally an issue on

higher-energy beamlines and those specifically designed for

total scattering experiments. However, absorption of a sample

needs to be considered when carrying out experiments on

the PD beamline. For example, at 21 keV, CeO2 in a 0.3 mm

capillary has �R = 1.59, compared with �R = 0.52 that can be

achieved on other beamlines that reach 60 keV. Data quality

is lower for highly absorbing samples in Debye–Scherrer

geometry as the Bragg intensity is dependent on the diffrac-

tion angle and scattering may not be from the entire sample

volume (Von Dreele & Rodriguez-Carvajal, 2008).

Any absorption contribution needs to be removed from the

measured intensity in a total scattering experiment prior to

Fourier transform. S(Q) needs a multiplicative correction

applied to remove absorption effects that dampen the inten-

sity at high Q (Peterson et al., 2003). Using the ad hoc method

of data correction in this work relies on the input of data

without absorption effects (Juhás et al., 2013). Although minor

absorption can be corrected using standard data analysis

programs, the significant peak intensity reduction observed

in a highly absorbing sample often means meaningful results

cannot be obtained.

research papers

332 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO J. Synchrotron Rad. (2023). 30, 327–339

Figure 2
Data for an Ni sample show the (a) difference in resolution for Qmax =
14 �1 to 18 �1, and (b) loss of resolution observed for Qmax = 14 �1

compared with Qmax = 18 �1. In (a) the dotted plot is the measured data,
and the line (black) shows the calculated model.

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Absorption can be minimized by employing a smaller

internal diameter capillary or diluting the sample with a

known material to reduce the quantity of highly absorbing

material. An alternative method used to reduce �R of highly

absorbing samples by the XRD1 beamline (5.5–14 keV) at

Laboratório Nacional de Luz Sı́ncrotron involved fixing a thin

layer of the material onto the outside of a capillary rather than

filling the capillary (Carvalho et al., 2017). Generally, diluting

with an amorphous material such as amorphous SiO2 to obtain

�R < 1 is recommended as sample preparation is more

straightforward and �R can be decreased further than is

achievable using a smaller internal diameter capillary.

However, the addition of amorphous diluents will contribute

to the PDF so the measured background should account for

this by being an equivalent capillary filled with dilutant. The

effect of absorption on the resultant PDF pattern was inves-

tigated using powdered Cu (undiluted) with �R ’ 2.27

(packing density = 5.28 g cm�3) and Cu (diluted), which was

mixed with amorphous SiO2 to reduce the absorption so that

�R ’ 0.9 (Cu + SiO2). A capillary filled with amorphous SiO2

was removed as the background.

A Rietveld refinement was carried out on the diluted and

undiluted Cu using a Pearson VII to describe the peak shape.

The structural parameters are presented in Table S2. The

refined ADP for the undiluted sample (0.296 Å2) was lower

than that determined for the diluted Cu (0.517 Å2) when the

ADPs were refined. However, when the ADP obtained for

the diluted sample was used for the undiluted Cu and fixed

[Fig. 3(b)], the structural model of the undiluted Cu predicted

the high-� reflections were lower intensity. The low-� reflec-

tions in the undiluted Cu are lower in intensity due to

absorption, so the model fits these while underestimating

the intensity of the high-angle peaks. Relative absorption

decreases as � increases as the high-angle reflections can

diffract from the surface and reduce absorption (Cullity, 1978).

These results show that absorption is greater for low-angle

reflections as they have a longer pathlength through the

sample.

Figs. 3(c) and 3(d) show there are additional artefacts in

S(Q) and F(Q) due to poor background subtraction when the

absorption contribution is not removed. Peterson et al. (2003)

showed that a sine wave can be introduced into the S(Q) from

a poorly corrected background. The artefacts manifest as a

curve in the baseline of these functions and propagate into the

PDF. The increased noise is also higher in the undiluted

sample as shown in Fig. 3(d). This is likely from lower counting

research papers

J. Synchrotron Rad. (2023). 30, 327–339 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO 333

Figure 3
Error is introduced into the PDF if highly absorbing samples are not diluted. (a) Comparison in baseline between the empty borosilicate capillary, SiO2,
diluted (Cu + SiO2) and undiluted Cu; (b) the diffracted intensities for undiluted Cu at high angles are stronger than what the structure model for Cu
would predict; (c) S(Q); and (d) F(Q) showing the difference in background subtraction of Cu.

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statistics as more photons are absorbed by the sample so fewer

are reaching the detector. The scattering from the empty

capillary shows the characteristic broad amorphous peak at

7–9� 2� [Fig. 3(a)] like the scattering of the diluted Cu. The

undiluted Cu pattern does not exhibit this broad capillary

scattering peak and the model does not appear to fit the data

well at low r. This indicates an increase in the error of the low-r

peak intensities. Figs. S5(a) and S5(b) show that the fit to the

undiluted Cu PDF is poorer compared with the Cu diluted

with SiO2 as demonstrated by difference plot and higher Rwp.

The difference in fit quality also has a clear effect on the

calculated ADP as shown in Table S3. Users of the PD

beamline will need to dilute highly absorbing samples to

minimize absorption and improve the quality of their PDF.

3.4. Counting time duration

Data for the Ni particles were collected for 10–900 s to

understand the effect of counting time on acceptable counting

duration for stable samples. Note that counting time is highly

sample-dependent but is generally longer than is required for

reciprocal space measurements. It is well known that a longer

measurement time will lead to better counting statistics, so the

optimum counting time needs to be balanced with an accep-

table counting time duration. This is also important at large-

scale facilities where the total beam time is limited. F(Q)

shows that the noise at higher Q decreases as counting time

increases from a reduction in statistical error [Fig. 4(a)], as

expected. The resultant PDFs in Fig. 4(b) show that the

intensity of the ripples relative to the peak intensity decreased

for the PDFs obtained with the higher counting time of 900 s

compared with 10 s. Most noticeable is the lower-quality PDF

obtained when collecting for only 10 s. The peaks at higher r

cannot be differentiated from the ripples in the background

and these prominent ripples contribute to the correlation peak

shape. The first correlation at 2.5 Å is asymmetric due to the

contribution of large ripples to the peak profile. Interpreting a

PDF peak profile with poor counting statistics is problematic

as these peaks are convoluted with a sine function that cannot

always be modelled well and this will affect the refined para-

meter values. Consequently, a low counting time affects the

quality of the PDF and the calculated structural data.

The lattice parameters determined from modelling the

PDFs were comparable for all counting times (Table S4).

However, the PDF collected for 900 s has the lowest Rwp.

These results also exemplify that counting times are sample

dependent. Rwp was lower for Ni (Table S1) powder than for

the Ni particles when all were collected for 240 s. The total

number of Ni atoms per sample volume interacting with the

beam is lower for the Ni particles (20 wt%) due to the

presence of carbon. Hence counting times for supported

nanoparticle samples can be longer if the scattering from the

particles is weak from dilution by the support, the particles are

a few nanometres in diameter and they are dispersed. Longer

counting times that ensure good counting statistics above 90�

2� may also result in backscatter contributing to the peak

intensities in reciprocal space. It is important to ensure that

the collected data are free from backscattering as this

contribution can undesirably contribute to the PDF, hence

contaminating the data. A compromise is needed between the

optimum acquisition time and data quality, so it is suggested

that an acquisition time of 600 s is acceptable for similar

samples.

3.5. Nanoparticle case study

Bimetallic Pt-based nanoparticles have applications as

electrocatalysts for formic acid and ethanol electro-oxidation

and oxygen reduction. Nanoparticles such as NiPt are

reported to have superior performance compared with

monometallic nanoparticles due to synergistic effects between

their elements as well as typically exhibiting a reduction in

surface poisoning (Zhang et al., 2018). The PDFs of a series of

metal particles, Ni, NiPt, dealloyed NiPt and Pt were obtained

to establish the data quality for nanomaterials at the PD

beamline. The PDF crystallite sizes were compared with those

obtained from TEM and the first three correlation lengths

were compared with those calculated using XAS.

research papers

334 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO J. Synchrotron Rad. (2023). 30, 327–339

Figure 4
Data for the Ni particles showing (a) noise in F(Q) at higher Q decreases
as the counting time increases, and (b) how the increase in statistical error
manifests in G(r). For (b), the dotted plot is the measured data and the
line (black) shows the refined model.

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3.5.1. Crystallite size distribution and morphology. The

crystallite size distribution and morphology were obtained for

the NiPt, dealloyed NiPt and Pt nanoparticles using STEM.

The HAADF signal in STEM mode is proportional to the

atomic number so measuring the crystallite size is facilitated

using STEM. Both NiPt and dealloyed NiPt possess round and

facetted single crystallites as shown in Figs. 5(b) and 5(c),

whereas the morphology of Pt appears more variable

[Fig. 5(d)]. Images of Ni were obtained using BF-TEM and

show that the particles are significantly larger than the NiPt,

dealloyed NiPt and Pt nanoparticles [Fig. 5(a)]. These differ-

ences in crystallite size are reflected in the reciprocal and real

space diffraction data. Fig. 8 shows that the Ni powder

diffraction pattern has sharp Bragg peaks while the nano-

particles have broad peaks. The NiPt and dealloyed NiPt

nanoparticles were also slightly larger than Pt as shown in

Table 1. The particle diameter histograms are presented in

Fig. S6, and additional STEM images are presented in Fig. S7.

3.5.2. Local environment from XANES and EXAFS. A

comparison with the structural parameters determined from

PDF was established for the supported particles. The EXAFS

data from Ni and Pt were fit using the predicted scattering of

the neat face-centred cubic structures. The plotted results of

the fit are given in Fig. 6, which show good agreement out to

5 Å and the third shell of atomic distances. The determined

radial distances between the absorbing atom and the indicated

shell are given in Table 2. EXAFS fit parameters of the Pt

and Ni nanoparticle analysis are presented in Table S5. A

comparison between the EXAFS radial distances and the PDF

correlation length is discussed in Section 3.5.3.

The Ni phase and Pt phase can be probed by examining

their respective edges. The PtNi nanoparticles were analysed

at both edges and compared with the Ni and Pt nanoparticles.

The spectra in Fourier transform (R) space are presented in

Fig. 7(a) and the radial distance functions are presented in

Fig. S8. It can be qualitatively observed that the Pt phase in

the NiPt and dealloyed NiPt nanoparticles exists predomi-

nately as the neat metal, closely resembling the spectra for Pt.

Both NiPt and dealloyed NiPt can be fit reasonably well with

only scattering from Pt–Pt and Pt–O in the first shell without

significant contribution from Ni. This would suggest that the

nanoparticles contain a relatively pure Pt phase. This is further

corroborated with a XANES analysis, in which the absorption

edge is identical between the Pt nanoparticles and the NiPt

and dealloyed NiPt [Fig. 7(b)]. In contrast, the Ni phase of the

NiPt and dealloyed NiPt differ significantly from the pure

nanoparticles and cannot be fit with only Ni–Ni and Ni–O

scattering paths. The XANES analysis likewise shows a

significant decrease in the pre-edge feature present in the Ni

nanoparticles, behaviour which is associated with NiPt alloy

formation [Fig. 7(c)]. This suggests that the Ni phase is not

pure and has Pt–Ni alloy characteristics (Chen et al., 2016).

3.5.3. Correlation lengths from PDFs. Nanometre-sized

crystallites have broad peaks as the diffracted intensity is

spread further from the reciprocal lattice points. To minimize

line broadening, crystallites are recommended to be 1–5 mm

to maintain a good power average (McCusker et al., 1999).

Fig. 8(a) shows that only the Ni possesses relatively narrow

Bragg peaks whereas the NiPt, dealloyed NiPt and Pt have

broader peaks due to the size of the crystallites.

The PDFs of Ni and NiPt, dealloyed NiPt, and Pt nano-

particles are shown in Fig. 8(b). The larger crystallite size and

long-range atomic order of Ni are reflected in the PDF as

correlations do not attenuate like that observed for NiPt,

dealloyed NiPt and Pt. The correlations for the nanoparticles

dampen by �15 Å due to their finite crystallite size. The

structures of all the nanoparticles from the PDFs were refined

using the space group Fm3m (No. 225) and the occupancy in

the 4a sites were split in the NiPt and dealloyed NiPt models,

i.e. the occupancy for Ni was 0.5 and Pt was 0.5. The ADP of

each Ni and Pt site in the NiPt and dealloyed NiPt model were

constrained. All nanoparticles were corrected for finite crys-

tallite size using a numerical spherical shape function (Usher

et al., 2018). Fits to the PDFs are shown in Fig. S9 and struc-

research papers

J. Synchrotron Rad. (2023). 30, 327–339 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO 335

Figure 5
(a) Ni consists of large crystallites as shown in the BF-TEM compared with (b) NiPt, (c) dealloyed NiPt and (d) Pt nanoparticles from the STEM-
HAADF images.

Table 1
Crystallite size of the nanoparticles determined from STEM.

Sample Size (nm) Number of particles

NiPt 3.1 (1) 532
Dealloyed NiPt 3.1 (1) 310
Pt 2.0 (1) 452

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tural details in Table S6. Microstrain, structural defects and

effects from the surface atom geometry which are often

observed in nanomaterials may be present in these samples

(Bertolotti et al., 2018). There was no improvement to the fit

when octahedral- and tetrahedron-shaped functions were

tested and the TEM data show that the crystallites for NiPt

and dealloyed NiPt were round and facetted. The size of the Pt

nanoparticle sample was 1.9 nm, which corresponds well with

the average particle size of 2.0 nm from TEM (Table 3). The

values obtained from the PDF for PtNi (2.2 nm) and dealloyed

PtNi (2.4 nm) are lower than the 3.1 nm obtained for both

samples using TEM. A limitation of TEM in the particle-size

distribution is that the number of particles sampled is orders

of magnitude lower than the number that are sampled using

X-ray diffraction. Particle sizes are obtained by measuring the

diameter from a 1D image so the length along other axes is

absent and may be a different length if the particle shape is

irregular. However, accurate particle sizes from modelling

diffraction data are also compromised if the fit quality is poor.

A correct model and reasonable starting parameters are

needed for least-squares minimization refinements from

existing knowledge of the sample. The difference between the

particle sizes from the PDF and TEM observed in this work

are proposed to be caused by the difference between how the

particle size is determined using both techniques.

The first three correlation lengths were determined from

the refined Ni and Pt structural models. For Ni these were

2.48 Å, 3.54 Å and 4.31 Å, and for Pt they were 2.76 Å, 3.91 Å

and 4.78 Å. Both the Ni and Pt correlation lengths agree well

with the values obtained using EXAFS. Correlations for the

NiPt and dealloyed NiPt nanoparticles are at larger r than the

corresponding peaks for Ni, and smaller r than the corre-

sponding peaks for Pt. This is due to the combination of the

two elements with different atomic sizes in the samples. The

correlations at 3.83 Å and 3.84 Å for the NiPt and dealloyed

NiPt are at positions closer to those of the Pt (3.91 Å) rather

than Ni (3.54 Å). This implies that the structure is closer to

Pt, rather than Ni, and both NiPt and dealloyed NiPt are not

a 50:50 random alloy. This conclusion is corroborated by

EXAFS. We conclude that accurate correlation lengths can

be determined from the total scattering data measured on the

PD beamline.

research papers

336 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO J. Synchrotron Rad. (2023). 30, 327–339

Table 2
EXAFS radial distances of Ni and Pt.

Here R is the radial distance and �2 is the Debye–Waller factor.

Ni–Ni Pt–Pt

R (Å) �2 (Å2) R (Å) �2 (Å2)

First shell 2.48 	 0.01 0.002 2.77 	 0.01 0.003
Second shell 3.51 	 0.01 0.003 3.92 	 0.01 0.004
Third shell 4.32 	 0.01 0.004 4.80 	 0.01 0.007

Figure 6
Radial distances determined using EXAFS for (a) Ni and (b) Pt, and the corresponding k-plots for (c) Ni and (d) Pt show good agreement with the PDF-
determined correlation lengths. The dotted (blue) spectra are the measured data and the line (red) spectra is the fitted model.

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4. Considerations

Total scattering data can be obtained on the PD beamline,

although there are constraints to the capabilities offered.

These include:

(i) Measurements require stable samples and longer

acquisition times. Collection times on the PD beamline can be

longer than at dedicated higher flux X-ray PDF beamlines.

Data should be collected over 124� 2� using the Mythen-II

positioned at four different starting angles. It takes �2 min to

physically move from 2.5� 2� (position 2) to 51.5� 2� (position

3, see Section 2.1) as the diffractometer moves the Mythen-II

at 0.4� per second. This excludes the time it takes to measure

the data. In the nanoparticle samples reported here, the total

measurement time is �18 min (240 s per position for four

positions plus 124 s to move the detector). In comparison, I15-

1 at Diamond Light Source has in situ battery sample envir-

onments than can collect PDF data in 2 min (Diaz-Lopez et al.,

2020). This makes non-ambient/in situ PDF measurements at

the PD beamline more challenging as the conditions must

remain stable throughout the whole data collection.

(ii) Dilution is essential for highly absorbing samples.

Artefacts will be observed in PDFs of highly absorbing

samples that are not diluted. This work shows that there are

significant effects on the resultant PDF for highly absorbing

samples, with the most noticeable effect on the calculated

research papers

J. Synchrotron Rad. (2023). 30, 327–339 Anita M. D’Angelo et al. � Total scattering measurements at ANSTO 337

Figure 7
(a) EXAFS Ni- and Pt-edge comparison of the NiPt and dealloyed NiPt
nanoparticles, and XANES plots of (b) Pt and (c) Ni.

Table 3
Crystallite size of the nanoparticles determined from PDF.

PtNi Dealloyed PtNi Pt

Sphere length (nm) 2.2 (1) 2.4 (1) 1.9 (1)

Figure 8
(a) Diffraction patterns and (b) PDFs of the Ni, NiPt, dealloyed NiPt and
Pt nanoparticles.

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ADPs. Absorption causes a reduction in low-angle Bragg peak

intensities and inaccuracies in background subtraction. It is

essential that highly absorbing samples are always diluted so

that �R < 1. Users at the PD beamline should calculate �R of

their samples at 21 keV if they are planning a total scattering

experiment and dilute if necessary.

(iii) Correlation differences >0.35 Å can be resolved.

Correlation lengths that differ by >0.35 Å can be resolved due

to the maximum momentum transfer of the PD beamline.

Users need to consider whether the real space resolution

offered by the PD beamline at 21 keV and an angular range of

124� 2� is appropriate for their experiment.

5. Summary

In this work we explored the capabilities of carrying out total

scattering experiments on the PD beamline, including inves-

tigations into the maximum resolution (Qmax) absorption

effects and counting time. The maximum momentum transfer

is 19 �1 if the data are collected at 21 keV. Systems typically

challenging to analyse using the Bragg peaks can be measured

on the PD beamline via total scattering experiments.

However, the PDF capability of the beamline can be further

developed. Future upgrades planned for the PD beamline

include a Mythen-III detector that will reduce data collection

time and improve data quality. It includes an increase in

angular range (150� 2�) that will achieve a higher momentum

transfer of 21 �1 if the data are collected at 22 keV for PDF

studies. The Mythen-II requires two patterns to be collected,

which are spliced together and normalized to remove gaps

in the data from physical gaps between the modules. The

measurement time will be halved using the Mythen-III as data

without gaps between the modules will be obtained in a single

pattern. These results detail the total scattering capability

offered and should be used as a guide for those considering

and designing total scattering experiments at the PD beamline.

Acknowledgements

The authors acknowledge the use of the instruments and

scientific and technical assistance at the Monash Centre for

Electron Microscopy, a node of Microscopy Australia. We also

thank the Australian Synchrotron scientific advisory panel for

their ongoing contribution to the development of the Powder

Diffraction beamline.

Funding information

This research used equipment funded by the Australian

Research Council (ARC) (grant No. LE0454166). ACYL

acknowledges support from the ARC (grant No.

FT180100594). The authors are grateful to the group of

Professor Shizhang Qiao for the synthesis of the nanoparticle

samples.

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