Synchrotron X-ray micro-tomography at the Advanced Light Source: Developments in high-temperature in-situ mechanical testing

Barnard, Harold; MacDowell, Alastair A.; Parkinson, Dilworth Y.; Mandal, Pratiti; Czabaj, Michael W.; Gao, Yan; Maillet, Emmanuel; Blank, Basil; Larson, Natalie M.; Ritchie, Robert O.; Gludovatz, Bernd; Acevedo, Claire; Liu, Dong

doi:10.1088/1742-6596/849/1/012043

Cited by 7 publications

(4 citation statements)

References 10 publications

(11 reference statements)

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“…Microtensile, microcantilever, and micropillar tests and their counterparts at the nanoscale have allowed researchers to carry out site-specific or volume-specific experiments and obtain the attendant mechanical response ( 3–5 ). These experiments have also been coupled with various diagnostic tools such as scanning electron microscopy (SEM), transmission electron microscopy (TEM), and other X-ray or beamline instruments that offer insights into deformation mechanisms and in situ tracking of key parameters such as texture/precipitate evolution, extent of slip behavior, and twin volume fractions ( 6–8 ) in metals.…”

Section: Introductionmentioning

confidence: 99%

High-throughput quantification of quasistatic, dynamic and spall strength of materials across 10 orders of strain rates

Eswarappa Prameela,

Walker,

DiMarco

et al. 2024

PNAS Nexus

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The response of metals and their microstructures under extreme dynamic conditions can be markedly different from that under quasistatic conditions. Traditionally, high strain rates and shock stresses are achieved using cumbersome and expensive methods such as the Kolsky bar or large spall experiments. These methods are low throughput and do not facilitate high-fidelity microstructure-property linkages. In this work, we combine two powerful small-scale testing methods, custom nanoindentation, and laser-driven micro-flyer shock, to measure the dynamic and spall strength of metals. The nanoindentation system is configured to test samples from quasistatic to dynamic strain rate regimes. The laser-driven micro-flyer shock system can test samples through impact loading, triggering spall failure. The model material used for testing is Magnesium alloys, which are lightweight, possess high-specific strengths, and have historically been challenging to design and strengthen due to their mechanical anisotropy. We adopt two distinct microstructures, solutionized (no precipitates) and peak-aged (with precipitates) to demonstrate interesting upticks in strain rate sensitivity and evolution of dynamic strength. At high shock loading rates, we unravel an interesting paradigm where the spall strength versus strain rate of these materials converges, but the failure mechanisms are markedly different. Peak aging, considered to be a standard method to strengthen metallic alloys, causes catastrophic failure, faring much worse than solutionized alloys. Our high throughput testing framework not only quantifies strength but also teases out unexplored failure mechanisms at extreme strain rates, providing valuable insights for the rapid design and improvement of materials for extreme environments.

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Section: Introductionmentioning

confidence: 99%

High-throughput quantification of quasistatic, dynamic and spall strength of materials across 10 orders of strain rates

Eswarappa Prameela,

Walker,

DiMarco

et al. 2024

PNAS Nexus

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“…X-ray micro-computed tomography (µCT) has been widely adopted to investigate internal microstructures and damage of multi-phase structural materials such as fiberreinforced composites [1][2][3][4][5][6][7][8][9][10]. In situ µCT experiments generate multiple 3D images, each consisting of 2000 slices (~30 gigabytes).…”

Section: Introductionmentioning

confidence: 99%

Validation of Deep Learning Segmentation of CT Images of Fiber-Reinforced Composites

et al. 2022

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Micro-computed tomography (µCT) is a valuable tool for visualizing microstructures and damage in fiber-reinforced composites. However, the large sets of data generated by µCT present a barrier to extracting quantitative information. Deep learning models have shown promise for overcoming this barrier by enabling automated segmentation of features of interest from the images. However, robust validation methods have not yet been used to quantify the success rate of the models and the ability to extract accurate measurements from the segmented image. In this paper, we evaluate the detection rate for segmenting fibers in low-contrast CT images using a deep learning model with three different approaches for defining the reference (ground-truth) image. The feasibility of measuring sub-pixel feature dimensions from the µCT image, in certain cases where the µCT image intensity is dependent on the feature dimensions, is assessed and calibrated using a higher-resolution image from a polished cross-section of the test specimen in the same location as the µCT image.

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“…[3][4][5] This has been employed to great effect in materials science research and development, with several notable micro-scale computed tomography (µCT) beamlines operating around the world. [6][7][8][9][10][11] Typical µCT systems image direct projections using rectilinear propagation from the sample to detector, where the spatial resolution of the scintillator detector is limited to 0.5 -1.0 um by depth of focus issues 12 associated with the visible light optical microscope objectives used to project the scintillator image onto a pixelated detector. NanoCT systems typically require x-ray zone plates as these optics, when fabricated to modern standards, have inherently higher spatial resolution compared to scintillators used in µCT systems.…”

Section: Introductionmentioning

confidence: 99%

The hard x-ray nanotomography microscope at the advanced light source

Nichols

Voltolini

Gilbert

et al. 2022

Review of Scientific Instruments

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Beamline 11.3.1 at the Advanced Light Source is a tender/hard (6-17 keV) X-ray beamline recently repurposed with a new full-field, nanoscale transmission X-ray microscope (nTXM). The endstation is suited to 50-250 µm samples of (generally) non-biological materials and has a theoretical resolution of 55 nm. The microscope is used in tandem with a 25 nm eccentricity rotation stage for high-resolution volume imaging using nanoscale computed tomography (nCT). The system also features a novel bipolar illumination condenser for the illumination of a ~100 µm spot of interest of the sample, followed by a phase-type zone plate magnifying objective with a ~52 m field of view, and a phase detection ring. The zone plate serves as the system objective and magnifies the sample with projection onto an indirect X-ray detection system, consisting of a polished single crystal CsI(Tl) scintillator and a range of high-quality plan fluorite visible light objectives that in turn project the final visible light image onto a water-cooled CMOS 2048x2048 pixel 2 detector. Here we will discuss the salient features of this instrument, and describe our initial efforts to experimentally observe the internal 3D micro-and nanostructure of some highlighted materials, including composites and rocks.

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Synchrotron X-ray micro-tomography at the Advanced Light Source: Developments in high-temperature in-situ mechanical testing

Cited by 7 publications

References 10 publications

High-throughput quantification of quasistatic, dynamic and spall strength of materials across 10 orders of strain rates

High-throughput quantification of quasistatic, dynamic and spall strength of materials across 10 orders of strain rates

Validation of Deep Learning Segmentation of CT Images of Fiber-Reinforced Composites

The hard x-ray nanotomography microscope at the advanced light source

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