I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[14696, 19579, 21682]
Open Access
Abstract: Multilayer monochromator devices are commonly used at (imaging) beamlines of synchrotron facilities to shape the X-ray beam to relatively small bandwidth and high intensity. However, stripe artefacts are often observed and can deteriorate the image quality. Although the intensity distribution of these artefacts has been described in the literature, their spectral distribution is currently unknown. To assess the spatio-spectral properties of the monochromated X-ray beam, the direct beam has been measured for the first time using a hyperspectral X-ray detector. The results show a large number of spectral features with different spatial distributions for a [Ru, B4C] strip monochromator, associated primarily with the higher-order harmonics of the undulator and monochromator. It is found that their relative contributions are sufficiently low to avoid an influence on the imaging data. The [V, B4C] strip suppresses these high-order harmonics even more than the former, yet at the cost of reduced efficiency.
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Dec 2019
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I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[19367]
Abstract: During CO2 storage in depleted oil fields, under immiscible conditions, CO2 can be trapped in the pore space by capillary forces, providing safe storage over geological times - a phenomenon named capillary trapping. Synchrotron X-ray imaging was used to obtain dynamic three-dimensional images of the flow of the three phases involved in this process - brine, oil and gas (nitrogen) - at high pressure and temperature, inside the pore space of Ketton limestone. First, using continuous imaging of the porous medium during gas injection, performed after waterflooding, we observed chains of multiple displacements between the three phases, caused by the connectivity of the pore space. Then, brine was re-injected and double capillary trapping - gas trapping by oil and oil trapping by brine - was the dominant double displacement event. We computed pore occupancy, saturations, interfacial area, mean curvature and Euler characteristic to elucidate these double capillary trapping phenomena, which lead to a high residual gas saturation. Pore occupancy and saturation results show an enhancement of gas trapping in the presence of both oil and brine, which potentially makes CO2 storage in depleted oil reservoirs attractive, combining safe storage with enhanced oil recovery through immiscible gas injection. Mean curvature measurements were used to assess the capillary pressures between fluid pairs during double displacements and these confirmed the stability of the spreading oil layers observed, which facilitated double capillary trapping. Interfacial area and Euler characteristic increased, indicating lower oil and gas connectivity, due to the capillary trapping events.
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Nov 2019
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I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[13237, 11076, 5003]
Abstract: Imaging techniques for quantifying changes in the hierarchical structure of deforming joints are constrained by destructive sample treatments, sample-size restrictions and lengthy scan times. Here, we report the use of fast low-dose pink-beam synchrotron X-ray tomography in combination with mechanical loading at nanometric precision for in situ imaging, at resolutions below 100 nm, of the mechanical strain in intact untreated joints under physiologically realistic conditions. We show that in young, older and osteoarthritic mice, hierarchical changes in tissue structure and mechanical behaviour can be simultaneously visualized, and that the tissue structure at the cellular level correlates with the mechanical performance of the whole joint. We also use the tomographic approach to study the colocalization of tissue strains to specific chondrocyte lacunar organizations within intact loaded joints and to explore the role of calcified-cartilage stiffness on the biomechanics of healthy and pathological joints.
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Nov 2019
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I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[4022]
Open Access
Abstract: Structural polymeric materials incorporating a microencapsulated liquid healing agent demonstrate the ability to autonomously heal cracks. Understanding how an advancing crack interacts with the microcapsules is critical to optimizing performance through tailoring the size, distribution and density of these capsules. For the first time, time-lapse synchrotron X-ray phase contrast computed tomography (CT) has been used to observe in three-dimensions (3D) the dynamic process of crack growth, microcapsule rupture and progressive release of solvent into a crack as it propagates and widens, providing unique insights into the activation and repair process. In this epoxy self-healing material, 150 µm diameter microcapsules within 400 µm of the crack plane are found to rupture and contribute to the healing process, their discharge quantified as a function of crack propagation and distance from the crack plane. Significantly, continued release of solvent takes place to repair the crack as it grows and progressively widens.
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Nov 2019
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I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[21327]
Abstract: X-ray Grating Talbot Interferometer (XGTI) is already routinely used for quantitative phase contrast imaging of soft tissue samples. XGTI can be realized using various measurement techniques, depending on the X-ray source used, the required spatial resolution and the speed of acquisition. The phase-stepping measurement technique, which is commonly used for XGTI data acquisition, needs multiple acquisitions for a single projection. For fast imaging the Moiré technique, a single-shot technique, is often preferred. However, it requires two gratings which increases the dose on the sample. We have therefore examined the Spatial Harmonic Imaging (SHI) technique which is low-dose and single-shot, using the I13-2 Diamond-Manchester Beamline at Diamond Light Source (DLS). The DLS I13-2 beamline is equipped with a Double Crystal Monochromator (DCM) and a Multi-Layer Monochromator (MLM) to deliver monochromatic beam, which work at the energy bandwidths (ΔE/E) of 10-4 and 10-2, respectively. However, the disadvantage of using these monochromators, especially for fast imaging, is loss of X-ray flux. It has already been shown that XGTI can work with an energy bandwidth (ΔE/E) of 10-1. Our aim is to develop a single phase grating interferometer with pink beam from an undulator source, with X-ray mirror optics and multiple absorption filters, to obtain maximum possible flux with sufficient coherence and monochromaticity. We demonstrate performance with optimized beamline parameters for a photon energy of 15 keV with some demonstrative image reconstructions.
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Oct 2019
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I13-1-Coherence
I13-2-Diamond Manchester Imaging
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Open Access
Abstract: The Diamond Beamline I13L is dedicated to micro- and nano- imaging, with two independently operating branchlines. The imaging branch preforms imaging in real space, with In-line phase contrast imaging and grating interferometry at micrometre resolution and full-field transmission microscopy up to 50nm spatial resolution. Highest spatial resolution is achieved on the coherence branchline, where diffraction imaging methods such as Ptychography and Bragg-CDI are performed. The article provides an update about the experimental capabilities at the beamline with an emphasis on the rapidly evolving ptychography capabilities. The latter has evolved to an user-friendly method with non-expert users able to explore their science without any specific a-priory knowledge.
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Oct 2019
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I13-1-Coherence
I13-2-Diamond Manchester Imaging
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Christoph
Rau
,
Malte
Storm
,
Shashidhara
Marathe
,
Andrew J.
Bodey
,
Marie-christine
Zdora
,
Silvia
Cipiccia
,
Darren
Batey
,
Xiaowen
Shi
,
Sven
Schroeder
,
Gunjan
Das
,
Melanie
Loveridge
,
Ralf
Ziesche
,
Brian
Connolly
Open Access
Abstract: The DIAMOND beamline I13L is dedicated to multi-scale and multi-modal imaging in real and reciprocal space. The beamline consists of two independently operating experimental stations, located at a distance of more than 200 m from the source. The Imaging Branch performs micro-tomography with in-line phase contrast in the 6-30 keV energy range. In addition, a grating interferometry setup and a full-field microscope for nano-tomography are currently implemented. Other techniques providing high-resolution three-dimensional information, in particular coherent X-ray diffraction, are hosted on the Coherence Branch. All imaging methods are tested to operate with large energy bandwidths and therefore shorter exposure times. To this end, two options are currently used: the so-called ‘pink-beam’ mode using a reflecting mirror and X-ray filters and monochromatic mode using a multilayer monochromator. The operation mode enables science for in-situ and operando studies across a wide range of scientific areas.
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Oct 2019
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I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[13750]
Open Access
Abstract: Lymph nodes (LN) are crucial for immune function, and comprise an important interface between the blood and lymphatic systems. Blood vessels (BV) in LN are highly specialized, featuring high endothelial venules across which most of the resident lymphocytes crossed. Previous measurements of overall lymph and BV flow rates demonstrated that fluid also crosses BV walls, and that this is important for immune function. However, the spatial distribution of the BV in LN has not been quantified to the degree necessary to analyse the distribution of transmural fluid movement. In this study, we seek to quantify the spatial localization of LNBV, and to predict fluid movement across BV walls. MicroCT imaging of murine popliteal LN showed that capillaries were responsible for approximately 75% of the BV wall surface area, and that this was mostly distributed around the periphery of the node. We then modelled blood flow through the BV to obtain spatially resolved hydrostatic pressures, which were then combined with Starling’s law to predict transmural flow. Much of the total 10 nL/min transmural flow (under normal conditions) was concentrated in the periphery, corresponding closely with surface area distribution. These results provide important insights into the inner workings of LN, and provide a basis for further exploration of the role of LN flow patterns in normal and pathological functions.
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Sep 2019
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I13-2-Diamond Manchester Imaging
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Rafael
Leiva-garcia
,
Adam
Anders
,
Tony
Cook
,
Grace
Burke
,
Chris
Muryn
,
Mary
Ryan
,
Malte
Storm
,
Silvia
Vargas
,
Philip
Withers
,
Brian
Connolly
,
James
Carr
,
Sheetal
Handa
Diamond Proposal Number(s):
[21142]
Abstract: Thick corrosion scales form within carbon steel oilfield pipelines in sweet (CO2 saturated) environments. The morphology and the extent of the resultant pseudo-protective nature of these scales has been seen to be dependent on multiple factors including solution pH, temperature, flow rate, and partial pressure of CO2 present. Different techniques (SEM, XRD, FIB, etc.) have been used in the past to characterise these corrosion scales. However, limitations in these techniques occur due to the fact that only small regions of the scale can be characterised in a feasible time. Further limitations may result in difficulty to relate local scale features with corrosion morphology on the evolving metal surface (i.e. localised corrosion) as the morphology of the substrate surface can only be characterised once the scale is removed. The aim of this work is to address this issue through the use of high resolution x-ray absorption tomography to characterise the internal morphology of the corrosion scales from ex situ specimens exposed to CO2 environments as a function of pH and temperature.
X-65 pipeline steel, high purity 99.99 Fe and low purity 99.0 Fe pins were used in these experiments. Specimens were exposed to CO2saturated solutions using two different methods, notably open circuit potential (OCP) immersion for 7-12 days and electrochemical polarisation for two hours at 200 mV(vs OCP). After the scaling experiments, samples were characterised using XRD and SEM. X-ray tomography was subsequently performed at the University of Manchester X-ray Imaging Facilities to characterise the corrosion morphology. Transmission X-ray microscopy (TXM) was used in absorption mode and phase contrast mode to obtain three dimensional reconstructions of the specimens, where the different features of the scale and the internal corroded substrate were imaged and characterised simultaneously.
Results indicate differences in the morphology of the corrosion scale depending on the method that was used to corrode the samples. As a consequence of the supersaturation in Fe2+, polarised samples present a thicker scale than the scales obtained by immersion at OCP conditions. The polarisation process also produces a less uniform corroded substrate than when the sample is immersed for 7 days at open circuit in the corroding environments used. In this work high resolution X-ray tomography has been proven to be a very powerful technique to study the scale morphology as well as the features of localised corrosion occurring under scale in the substrate.
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Sep 2019
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I13-2-Diamond Manchester Imaging
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Diamond Proposal Number(s):
[19829]
Abstract: X-ray grating interferometry (XGI) is a phase-contrast imaging technique that allows for a quantitative measurement of the refractive index with high density resolution in a model-independent manner—i.e. without a priori knowledge of the specimen composition. However, the retrieval of the X-ray wavefront phase shift relies on the accurate measurement of the interference pattern phase shift, making XGI vulnerable to phase wrapping when the interference pattern phase shift, related to the derivative of the wavefront phase shift, is large. Standard procedure for avoiding phase wrapping involves submerging the specimen in a water bath to reduce the mismatch of the index of refraction at the boundaries, but this requires a top-down rotation stage and is susceptible to gas bubble formation inside the water bath. Our team has presented an algorithm to remove phase wrapping artifacts for cylindrically shaped specimens that is applied to the phase-retrieved sinogram. This algorithm models and replaces phase-wrapped data to prevent the spread of “cupping” artifacts due to the integration of the differential phase during reconstruction. We give a criterion for selecting the modeling parameters so that the resulting measurement of the index of refraction matches the results of measurements without phase wrapping. We also apply this technique to cases where phase wrapping occurs at multiple interfaces. This algorithm allows for XGI measurements without a water bath and top-down rotation stage at synchrotron and laboratory facilities, especially as sensitivity increases.
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Sep 2019
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