Your search keyword '"Strain mapping"' showing total 216 results

1. Comparative electron diffraction analysis of strain relaxation in AlxGa1-xN materials in the microelectronics industry: 4D-STEM approach vs. TEM-based N-PED solution

Author

Drouillas, Estève, Mattei, Jean-Gabriel, and Warot-Fonrose, Bénédicte

Published

2025

2. Microscopic Strain Mapping: Functional Diversity and Their Demands.

Author

Motomichi Koyama, Kazuyuki Shimizu, Shien Ri, Norimitsu Koga, Hideaki Nishikawa, Tatsuya Morikawa, and Hiroshi Fudouzi

Abstract

This paper reviews recent demands and developments of microscopic strain mapping towards understanding plasticity--related fracture mechanisms in metals. After development of the most solid strain mapping method, i.e., micro--grid method, various strain mapping methods with different demands have been proposed. For instance, to satisfy the requirements of strain accuracy, spatial resolution, temporal resolution, view field range, strain limit, etc., digital image correlation (DIC) method, sampling moiré method, and photonic opal crystal film have been developed and improved. Furthermore, to understand true origins of fractures, regressive strain mapping, three--dimensional strain mapping, and post--mortem strain mapping have been increasingly required for the situations of "nobody knows the crack nucleation site before cracking", "stress--driven cracking occurs on a plane strain condition (specimen interior)", and "in some instances, only a fractured sample is available". For these demands, DIC method on replicas, computed--tomography--based strain mapping technique, and orientation--based strain analysis have been developed. In this paper, based on our recent works, the state--of--the--art techniques of strain mapping in metals are briefly introduced. [ABSTRACT FROM AUTHOR]

Published

2024

3. A Review: Non-Contact and Full-Field Strain Mapping Methods for Experimental Mechanics and Structural Health Monitoring.

Author

Meng, Wei, Bachilo, Sergei M., Weisman, R. Bruce, and Nagarajaiah, Satish

Subjects

*STRAIN sensors, *STRUCTURAL mechanics, *STRUCTURAL health monitoring, *DETECTORS

Abstract

Non-contact and full-field strain mapping captures strain across an entire surface, providing a complete two-dimensional (2D) strain distribution without attachment to sensors. It is an essential technique with wide-ranging applications across various industries, significantly contributing to experimental mechanics and structural health monitoring. Although there have been reviews that focus on specific methods, such as interferometric techniques or carbon nanotube-based strain sensors, a comprehensive comparison that evaluates these diverse methods together is lacking. This paper addresses this gap by focusing on strain mapping techniques specifically used in experimental mechanics and structural health monitoring. The fundamental principles of each method are illustrated with specific applications. Their performance characteristics are compared and analyzed to highlight strengths and limitations. The review concludes by discussing future challenges in strain mapping, providing insights into potential advancements and developments in this critical field. [ABSTRACT FROM AUTHOR]

Published

2024

4. High‐resolution strain mapping in a thermionic LaB6 scanning electron microscope.

Author

Poole, Benjamin, Marsh, Alex, Lunt, David, Hardie, Chris, Gorley, Mike, Hamelin, Cory, and Harte, Allan

Subjects

*SCANNING electron microscopes, *DIGITAL image correlation, *SCANNING electron microscopy, *NUCLEAR fusion, *HEAT sinks

Abstract

The high source stability and brightness of field emission gun equipped scanning electron microscopes (SEM) makes them ideal for high‐resolution digital image correlation (HRDIC). However, their high initial capital cost can be prohibitive for research organisations and groups. Conventional thermionic SEMs using either a tungsten hairpin or LaB6 filament are far more widespread due to their lower cost. Whilst it is understood that overall performance and ultimate resolution are lower than field emission SEMs, we propose that there is no fundamental reason why these instruments are unsuitable for HRDIC. We investigate the use of a LaB6 SEM as a viable tool for HRDIC. We detail the subtleties of performing HRDIC using a LaB6 thermionic source SEM, providing technical recommendations for best practices in using these instruments for strain mapping. The effects of instrument parameters on strain measurement noise are examined, with a focus on parameters of key relevance to in situ and ex situ mechanical testing. Errors in focus and image pixel size are found to be the primary contributors to the strain noise floor values, with stage accuracy being of secondary importance. We present a case study in oxygen‐free high‐conductivity copper, OFHC‐Cu, which is used in the designs of nuclear fusion components as a heat sink interlayer. Heterogeneous strain patterns are observed in this material, with high levels of strain localisation at grain boundaries. Active slip systems are identified using the relative displacement ratio method, demonstrating the quality of these data and the suitability of LaB6 instruments for HRDIC strain mapping, achieving performance approaching that expected of a field emission SEM. [ABSTRACT FROM AUTHOR]

Published

2024

5. 4D‐STEM Nanoscale Strain Analysis in van der Waals Materials: Advancing beyond Planar Configurations.

Author

Bolhuis, Maarten, van Heijst, Sabrya E., Sangers, Jeroen J. M., and Conesa‐Boj, Sonia

Abstract

Achieving nanoscale strain fields mapping in intricate van der Waals (vdW) nanostructures, like twisted flakes and nanorods, presents several challenges due to their complex geometry, small size, and sensitivity limitations. Understanding these strain fields is pivotal as they significantly influence the optoelectronic properties of vdW materials, playing a crucial role in a plethora of applications ranging from nanoelectronics to nanophotonics. Here, a novel approach for achieving a nanoscale‐resolved mapping of strain fields across entire micron‐sized vdW nanostructures using four‐dimensional (4D) scanning transmission electron microscopy (STEM) imaging equipped with an electron microscope pixel array detector (EMPAD) is presented. This technique extends the capabilities of STEM‐based strain mapping by means of the exit‐wave power cepstrum method incorporating automated peak tracking and K‐means clustering algorithms. This approach is validated on two representative vdW nanostructures: a two‐dimensional (2D) MoS2 thin twisted flakes and a one‐dimensional (1D) MoO3/MoS2 nanorod heterostructure. Beyond just vdW materials, the versatile methodology offers broader applicability for strain‐field analysis in various low‐dimensional nanostructured materials. This advances the understanding of the intricate relationship between nanoscale strain patterns and their consequent optoelectronic properties. [ABSTRACT FROM AUTHOR]

Published

2024

6. Age and gender differences in lumbar intervertebral disk strain using mechanical loading magnetic resonance imaging.

Author

Menon, Rajiv G., de Moura, Hector L., Kijowski, Richard, and Regatte, Ravinder R.

Subjects

INTERVERTEBRAL disk, STRAINS & stresses (Mechanics), AGE differences, MAGNETIC resonance imaging, DEAD loads (Mechanics)

Abstract

The objective of the current study was to investigate age‐ and gender‐related differences in lumbar intervertebral disk (IVD) strain with the use of static mechanical loading and continuous three‐dimensional (3D) golden‐angle radial sparse parallel (GRASP) MRI. A continuous 3D‐GRASP stack‐of‐stars trajectory of the lumbar spine was performed on a 3‐T scanner with static mechanical loading. Compressed sensing reconstruction, motion deformation maps, and Lagrangian strain maps during loading and recovery in the X‐, Y‐, and Z‐directions were calculated for segmented IVD segments from L1/L2 to L5/S1. Mean IVD height was measured at rest. Spearman coefficients were used to evaluate the associations between age and global IVD height and global IVD strain. Mann–Whitney tests were used to compare global IVD height and global IVD strain in males and females. The prospective study enrolled 20 healthy human volunteers (10 males, 10 females; age 34.6 ± 11.4 [mean ± SD], range 22–56 years). Significant increases in compressive strain were observed with age, as evidenced by negative correlations between age and global IVD strain during loading (ρ = −0.76, p = 0.0046) and recovery (ρ = −0.68, p = 0.0251) in the loading X‐direction. There was no significant correlation between age and global IVD height, global IVD strain during loading and recovery in the Y‐direction, and global IVD strain during loading and recovery in the Z‐direction. There were no significant differences between males and females in global IVD height and global IVD strain during loading and recovery in the X‐, Y‐, and Z‐directions. It was concluded that our study demonstrated the significant role aging plays in internal dynamic strains in the lumbar IVD during loading and recovery. Older healthy individuals have reduced IVD stiffness and greater IVD compression during static mechanical loading of the lumbar spine. The GRASP‐MRI technique demonstrates the feasibility to identify changes in IVD mechanical properties with early IVD degeneration due to aging. [ABSTRACT FROM AUTHOR]

Published

2023

7. Multi‐Material Strain Mapping with Scanning Reflectance Anisotropy Microscopy.

Author

Sendra, Joan, Haake, Fabian, Calvo, Micha, Galinski, Henning, and Spolenak, Ralph

Subjects

*MICROSCOPY, *OPTICAL devices, *ANISOTROPY, *REFLECTANCE, *REFLECTANCE measurement, *NEAR-field microscopy, *SEMICONDUCTOR devices

Abstract

Strain‐engineering of materials encompasses significant elastic deformation and leads to breaking of the lattice symmetry and as a consequence to the emergence of optical anisotropy. However, the capability to image and map local strain fields by optical microscopy is currently limited to specific materials. Here, a broadband scanning reflectance anisotropy microscope as a phase‐sensitive multi‐material optical platform for strain mapping is introduced. The microscope produces hyperspectral images with diffraction‐limited sub‐micron resolution of the near‐normal incidence ellipsometric response of the sample, which is related to elastic strain by means of the elasto‐optic effect. Cutting edge strain sensitivity is demonstrated using a variety of materials, such as metasurfaces, semiconductors, and metals. The versatility of the method to study the breaking of the lattice symmetry by simple reflectance measurements opens up the possibility to carry out non‐destructive mechanical characterization of multi‐material components, such as wearable electronics and optical semiconductor devices. [ABSTRACT FROM AUTHOR]

Published

2023

8. Virtual blebbistatin: A robust and rapid software approach to motion artifact removal in optical mapping of cardiomyocytes.

Author

Woodhams, Louis G., Jingxuan Guo, Schuftan, David, Boyle, John J., Pryse, Kenneth M., Elson, Elliot L., Huebsch, Nathaniel, and Genin, Guy M.

Subjects

*INDUCED pluripotent stem cells, *CARDIAC contraction, *MYOCARDIUM

Abstract

Fluorescent reporters of cardiac electrophysiology provide valuable information on heart cell and tissue function. However, motion artifacts caused by cardiac muscle contraction interfere with accurate measurement of fluorescence signals. Although drugs such as blebbistatin can be applied to stop cardiac tissue from contracting by uncoupling calcium-contraction, their usage prevents the study of excitation-contraction coupling and, as we show, impacts cellular structure. We therefore developed a robust method to remove motion computationally from images of contracting cardiac muscle and to map fluorescent reporters of cardiac electrophysiological activity onto images of undeformed tissue. When validated on cardiomyocytes derived from human induced pluripotent stem cells (iPSCs), in both monolayers and engineered tissues, the method enabled efficient and robust reduction of motion artifact. As with pharmacologic approaches using blebbistatin for motion removal, our algorithm improved the accuracy of optical mapping, as demonstrated by spatial maps of calcium transient decay. However, unlike pharmacologic motion removal, our computational approach allowed direct analysis of calcium-contraction coupling. Results revealed calcium-contraction coupling to be more uniform across cells within engineered tissues than across cells in monolayer culture. The algorithm shows promise as a robust and accurate tool for optical mapping studies of excitation-contraction coupling in heart tissue. [ABSTRACT FROM AUTHOR]

Published

2023

9. Development of TiO2 decorated Fe2O3QDs/g-C3N4 Ternary Z-scheme photocatalyst involving the investigation of phase analysis via strain mapping and its photocatalytic performance under visible light illumination

Author

Iqbal, S., Liu, J., Ma, H., Liu, W., Zuo, S., Yu, Y., and Khan, A.

Subjects

*IRRADIATION, *VISIBLE spectra, *ENERGY dispersive X-ray spectroscopy, *ANALYTICAL chemistry, *SOLAR energy conversion, *X-ray photoelectron spectroscopy, *ELECTRON energy loss spectroscopy

Abstract

This study reported the fabrication of TiO2-decorated Fe2O3QDs/g-C3N4 ternary Z-scheme photocatalyst via low-temperature calcination followed by a nonaqueous route with tunable particle size and strong interfacial contact. The subsequent Fe2O3QDs/g-C3N4 and TiO2/Fe2O3QDs/g-C3N4 were investigated in terms of structure, morphology, optical properties, and surface chemical composition analysis via transmission electron microscopy (TEM), X-ray photoelectron spectroscopy (XPS), energy dispersive x-ray spectroscopy (EDX), UV–visible spectroscopy, ESR and photoluminescence spectroscopy (PL). The crystalline parameters of the samples were investigated by X-ray diffraction (XRD) The Williamson-Hall method and geometrical phase analysis of HRTEM micrographs were employed to investigate lattice defects. Under visible light, the photocatalytic capabilities of as-fabricated TiO2/Fe2O3QDs/g-C3N4 were examined by degrading Rhodamine B (RhB), and an enhancement in photocatalytic efficacy was found. TiO2 works as a primary photosensitizer, providing extra photoinduced electrons influenced by oxygen vacancies, while Fe2O3 acts as a "bridge" for electron transport from the TiO2 moiety to the g-C3N4 thereby establishing an indirect charge transport pathway based on the Z-scheme. Radical scavenging tests were conducted to further explore the cause of increased activity and degradation mechanisms. Designing materials with oxygen vacancies and optimized structures can lead to improved solar energy conversion capabilities, particularly regarding contaminant removal. The proposed technique might be a viable option for the removal of rhodamine b compounds and for remedying freshwater reservoirs. TiO2 /Fe2O3QDs/g-C3N4Ternary Z-Scheme Photocatalysts! A facile strategy is exploited to modulate the crystallinity and surface properties of TiO2. TiO2 is incorporated into Fe2O3QDs/g-C3N4 through solvothermal treatment, which results in the formation of surface flaws and lattice-oxygen activated regions as well as the transformation of the Fe2O3QDs/g-C3N4 heterojunction into an indirect z-scheme system by rational modulation of the band alignment of two systems. The electron–hole pair is efficiently separated, conserving the electron reduction capability and the electron oxidation capability of the hole. The adapted structure and mesocrystalline nature resulted in a 7.3-fold improvement in the photocatalytic performance of TFCN over pure g-C3N4. [ABSTRACT FROM AUTHOR]

Published

2023

10. Application of 4-D ultrasound-derived regional strain and proteomics analysis in Nkx2-5-deficient male mice.

Author

Damen, Frederick W., Gramling, Daniel P., Wheatcraft, Dorothy Ahlf, Wilpan, Robert Y., Costa, Mauro W., and Goergen, Craig J.

Subjects

*PROTEOMICS, *LEFT ventricular dysfunction, *HEART diseases, *OXIDATIVE phosphorylation, *ENERGY metabolism

Abstract

The comprehensive characterization of cardiac structure and function is critical to better understanding various murine models of cardiac disease. We demonstrate here a multimodal analysis approach using high-frequency four-dimensional ultrasound (4DUS) imaging and proteomics to explore the relationship between regional function and tissue composition in a murine model of metabolic cardiomyopathy (Nkx2-5183P/+). The presented 4DUS analysis outlines a novel approach to mapping both circumferential and longitudinal strain profiles through a standardized framework. We then demonstrate how this approach allows for spatiotemporal comparisons of cardiac function and improved localization of regional left ventricular dysfunction. Guided by observed trends in regional dysfunction, our targeted Ingenuity Pathway Analysis (IPA) results highlight metabolic dysregulation in the Nkx2-5183P/+ model, including altered mitochondrial function and energy metabolism (i.e., oxidative phosphorylation and fatty acid/lipid handling). Finally, we present a combined 4DUS-proteomics z-score-based analysis that highlights IPA canonical pathways showing strong linear relationships with 4DUS biomarkers of regional cardiac dysfunction. The presented multimodal analysis methods aim to help future studies more comprehensively assess regional structure-function relationships in other preclinical models of cardiomyopathy. NEW & NOTEWORTHY A multimodal approach using both four-dimensional ultrasound (4DUS) and regional proteomics can help enhance our investigations of murine cardiomyopathy models. We present unique 4DUS-derived strain maps that provide a framework for both cross-sectional and longitudinal analysis of spatiotemporal cardiac function. We further detail and demonstrate an innovative 4DUS-proteomics z-score-based linear regression method, aimed at characterizing relationships between regional cardiac dysfunction and underlying mechanisms of disease. [ABSTRACT FROM AUTHOR]

Published

2023

11. Neutron Bragg edge imaging for strain characterization in powder bed additive manufacturing environments

Author

Shieren Sumarli, Efthymios Polatidis, Florencia Malamud, Matteo Busi, Claire Navarre, Reza Esmaeilzadeh, Roland Logé, and Markus Strobl

Subjects

Laser powder bed fusion, Neutron bragg edge imaging, Neutron transmission analysis, Neutron diffraction, Non-destructive strain measurement, Strain mapping, Mining engineering. Metallurgy, TN1-997

Abstract

Spatially resolved studies of crystalline structures, e.g. lattice spacings, are enabled by recording the transmitted spectra in neutron Bragg edge imaging. The recorded signals are, however, a result of through-thickness averaging of the probed specimen in the beam direction. Therefore, it is challenging to extract the strain distribution when the strain varies across the thickness, which applies for studies on different materials or material states along the beam. Here we introduce the approach to disentangle contributions to the recorded signals, i.e. separating the transmission spectra of two different material states. This is particularly applicable to powder bed additive manufacturing environments where operando strain characterization of the printed specimen using neutrons is intended. In this work, Laser Powder Bed Fusion (PBF-LB/M)-built 316L and IN718 samples embedded in their corresponding powders are used, extracting the desired spectra of the printed specimen. The disentanglement is proven to be satisfactory by obtaining coinciding strain maps of identical specimens embedded in powder layers of different thicknesses. Furthermore, the obtained residual strain distributions of 316L samples were verified by conventional neutron diffraction with lower spatial resolution due to the gauge volume averaging.

Published

2022

12. Unveiling Structural Heterogeneity and Imbalance of Gold Decahedral Nanoparticles using Four-dimensional Scanning Transmission Electron Microscopy

Author

Lin Oliver, Lyu Zhiheng, Ni Hsu-Chih, Jia Yetong, Zhao Kejie, Zuo Jian-Min, and Chen Qian

Subjects

4d-stem, multi-twinned nanostructure, strain mapping, Microbiology, QR1-502, Physiology, QP1-981, Zoology, QL1-991

Published

2024

13. Extending 4D-STEM based strain mapping to polycrystalline materials

Author

Schretter Lukas, Eckert Jürgen, and Gammer Christoph

Subjects

in-situ, strain mapping, 4d-stem, acom-tem, Microbiology, QR1-502, Physiology, QP1-981, Zoology, QL1-991

Published

2024

14. Dynamic observation of a damping material using micro X-ray computed tomography coupled with a phase-locked loop

Author

Masami Matsubara, Taichi Komatsu, Ryo Takara, Masakazu Kobayashi, Shogo Furuta, Kentaro Uesugi, Asahiro Nagatani, Shozo Kawamura, and Daiki Tajiri

Subjects

In-situ computed tomography, Cyclic loading, Damping material, Loss factor, Rubber microstructure, Strain mapping, Polymers and polymer manufacture, TP1080-1185

Abstract

As rubber materials are used for damping, clarifying the relationship between the loss factor and microstructure would help develop high-performance damping materials. Although nondestructive observations using X-ray computed tomography (CT) under repetitive deformation have been reported, no observations have been reported at the submicron order that capture low-strain deformation, such as vibration exposure. The internal deformation behavior of materials with different loss factors has not yet been evaluated. This study proposes a dynamic X-ray CT method for specimens under tensile amplitudes, directly evaluating the internal deformation behavior of materials under dynamic conditions. The proposed 4D-CT has an excitation of 1 Hz and a spatial resolution of 0.5 μm. The local strain was obtained from X-ray CT at each phase, and the deformation behavior was evaluated. The results revealed that the peak of the local strain amplitude distribution curve decreased and the distribution widened as fine particles were mixed.

Published

2023

15. Center Atom Model for Strain Mapping of Void and Crack of Atomic Lattice Image.

Author

Li, Yi‐xuan, Gao, Ying‐jun, Liao, Kun, Deng, Qian‐qian, Huang, Zong‐ji, Yi, Xiao‐Ai, and Luo, Zhi‐rong

Subjects

*ATOMIC models, *VOIDS (Crystallography), *SURFACE defects, *CRYSTAL defects, *CRYSTAL grain boundaries

Abstract

Aiming at the strain distribution around the atomic lattice defect with void and crack in crystal materials, a new elastic strain calculation method named as center atom model (CAM) is proposed in this work, and is applied for mapping the strain field of the defect with void in an atomic image lattice in real space under external forcing. As an example, the strain mapping of voids and cracks of an atomic lattice image from phase field crystal (PFC) model is quantitatively characterized by CAM. The results show that CAM can well be used to extract the strain information from various types of the defect surface of atomic lattice images. Wherever the strain distribution around the dislocation of the grain boundary or the strain around the void and crack is, CAM can accurately extract the strain distribution of the distortion area of the atomic lattice. CAM can also be easily extended and applied to the strain mapping of the defects in the heterogeneous interface. [ABSTRACT FROM AUTHOR]

Published

2022

16. Novel Elastography-Inspired Approach to Angiographic Visualization in Optical Coherence Tomography.

Author

Zykov, Alexey A., Matveyev, Alexander L., Matveev, Lev A., Shabanov, Dmitry V., and Zaitsev, Vladimir Y.

Subjects

ANGIOGRAPHY, HIGHPASS electric filters, OPTICAL tomography, COHERENCE (Optics), VISUALIZATION, BLOOD flow, OPTICAL coherence tomography

Abstract

In this paper, we present a new approach to contrast-agent-free angiographic visualization in optical coherence tomography (OCT). The proposed approach has much in common with imaging of local interframe strains in OCT-based elastography and utilizes the fact that the interframe motion of blood particles leads to discontinuity of strains within the vessel cross section. By this reasoning, we call this approach "elastography-inspired". Here, we first elucidate the essence and main features of the elastography-inspired approach using numerical simulation of OCT data. The simulations allow one to introduce both moving scatterers imitating blood flow in vessels as well as various masking motions imitating natural motions of living "solid" tissue surrounding the vessels. Second, using real OCT signals, we present comparative results of angiographic processing using the proposed elastography-inspired approach and a realization of OCA based on high-pass filtering of temporal variability of a series of OCT B-scans. The two methods can use the same initial dataset and the high-pass filtering OCA has already been routinely applied in both animal experiments and on patients. The new elastography-inspired method has a similar computational efficiency, and it is intrinsically able to compensate spatially-inhomogeneous masking tissue motions and demonstrates high robustness with respect to motion artefacts. Thus, the new approach looks very promising for enabling wider application of OCA in both laboratory studies on animals and, most importantly, for wider clinical applications on patients. [ABSTRACT FROM AUTHOR]

Published

2022

17. Precise strain mapping of nano-twinned axial ZnTe/CdTe hetero-nanowires by scanning nanobeam electron diffraction.

Author

Kryvyi, Serhii, Kret, Slawomir, and Wojnar, Piotr

Subjects

*NANOWIRES, *ELECTRON diffraction, *HOUGH transforms, *SPATIAL resolution, *OPTICAL properties, *DATA mapping, *HETEROSTRUCTURES

Abstract

The occurrence of strain is inevitable for the growth of lattice mismatched heterostructures. It affects greatly the mechanical, electrical and optical properties of nano-objects. It is also the case for nanowires which are characterized by a high surface to volume ratio. Thus, the knowledge of the strain distribution in nano-objects is critically important for their implementation into devices. This paper presents an experimental data for II-VI semiconductor system. Scanning nanobeam electron diffraction strain mapping technique for hetero-nanowires characterized by a large lattice mismatch (>6% in the case of CdTe/ZnTe) and containing segments with nano-twins has been described. The spatial resolution of about 2 nm is 10 times better than obtained in synchrotron nanobeam systems. The proposed approach allows us to overcome the difficulties related to nanowire thickness variations during the acquisition of the nano-beam electron diffraction data. In addition, the choice of optimal parameters used for the acquisition of nano-beam diffraction data for strain mapping has been discussed. The knowledge of the strain distribution enables, in our particular case, the improvement of the growth model of extremely strained axial nanowires synthetized by vapor-liquid solid growth mechanism. However, our method can be applied for the strain mapping in nanowire heterostructures grown by any other method. [ABSTRACT FROM AUTHOR]

Published

2022

18. Strain distribution visualization of punched electrical steel sheets using neutron Bragg-edge transmission imaging.

Author

Sasada, Seiji, Takahashi, Yoshihito, Takeuchi, Keisuke, Hiroi, Kosuke, Su, Yuhua, Shinohara, Takenao, Watanabe, Kenichi, and Uritani, Akira

Abstract

Residual strains in a punched electrical steel sheet increase the iron loss in the steel sheet. To accurately estimate the effect of residual strain on iron loss, the residual strain distribution in a punched electrical steel sheet should be evaluated. In this study, we demonstrated the two-dimensional imaging of the residual strain distribution in a punched electrical steel sheet using the neutron Bragg-edge transmission imaging method. To improve the accuracy of strain measurement with minimal deterioration of spatial resolution, we applied a process of superposing many specimen images. The tensile strain near the punched edge and the compressive strain inside the core were experimentally confirmed using this method. Finally, the neutron Bragg-edge imaging results and those obtained from kernel average misorientation map using electron backscattered diffraction were compared to verify the validity of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2022

19. Adaptive sampling for accelerating neutron diffraction-based strain mapping

Author

S V Venkatakrishnan, Chris M Fancher, Maxim Ziatdinov, Rama Vasudevan, Kyle Saleeby, James Haley, Dunji Yu, Ke An, and Alex Plotkowski

Subjects

Gaussian process regression, Bayesian optimization, neutron diffraction, strain mapping, Computer engineering. Computer hardware, TK7885-7895, Electronic computers. Computer science, QA75.5-76.95

Abstract

Neutron diffraction is a useful technique for mapping residual strains in dense metal objects. The technique works by placing an object in the path of a neutron beam, measuring the diffracted signals and inferring the local lattice strain values from the measurement. In order to map the strains across the entire object, the object is stepped one position at a time in the path of the neutron beam, typically in raster order, and at each position a strain value is estimated. Typical dwell times at neutron diffraction instruments result in an overall measurement that can take several hours to map an object that is several tens of centimeters in each dimension at a resolution of a few millimeters, during which the end users do not have an estimate of the global strain features and are at risk of incomplete information in case of instruments outages. In this paper, we propose an object adaptive sampling strategy to measure the significant points first. We start with a small initial uniform set of measurement points across the object to be mapped, compute the strain in those positions and use a machine learning technique to predict the next position to measure in the object. Specifically, we use a Bayesian optimization based on a Gaussian process regression method to infer the underlying strain field from a sparse set of measurements and predict the next most informative positions to measure based on estimates of the mean and variance in the strain fields estimated from the previously measured points. We demonstrate our real-time measure-infer-predict workflow on additively manufactured steel parts—demonstrating that we can get an accurate strain estimate even with 30%–40% of the typical number of measurements—leading the path to faster strain mapping with useful real-time feedback. We emphasize that the proposed method is general and can be used for fast mapping of other material properties such as phase fractions from time-consuming point-wise neutron measurements.

Published

2023

20. Framework of compressive sensing and data compression for 4D-STEM.

Author

Ni, Hsu-Chih, Yuan, Renliang, Zhang, Jiong, and Zuo, Jian-Min

Subjects

*SCANNING transmission electron microscopy, *DATA compression, *LOSSY data compression

Abstract

• A dual-space compressive sensing method is developed for the collection and reconstruction of 4D-STEM data at high fidelity. • The approach is tested on the subsampled datasets created from a full 4D-STEM dataset of a nanodevice sample, and demonstrated experimentally using random scan in real-space. • The same reconstruction algorithm can be used for compression of 4D-STEM datasets, leading to a large reduction (100 times or more) in data size, while retaining the fine features of 4D-STEM imaging. Four-dimensional Scanning Transmission Electron Microscopy (4D-STEM) is a powerful technique for high-resolution and high-precision materials characterization at multiple length scales, including the characterization of beam-sensitive materials. However, the field of view of 4D-STEM is relatively small, which in absence of live processing is limited by the data size required for storage. Furthermore, the rectilinear scan approach currently employed in 4D-STEM places a resolution- and signal-dependent dose limit for the study of beam sensitive materials. Improving 4D-STEM data and dose efficiency, by keeping the data size manageable while limiting the amount of electron dose, is thus critical for broader applications. Here we introduce a general method for reconstructing 4D-STEM data with subsampling in both real and reciprocal spaces at high fidelity. The approach is first tested on the subsampled datasets created from a full 4D-STEM dataset, and then demonstrated experimentally using random scan in real-space. The same reconstruction algorithm can also be used for compression of 4D-STEM datasets, leading to a large reduction (100 times or more) in data size, while retaining the fine features of 4D-STEM imaging, for crystalline samples. [ABSTRACT FROM AUTHOR]

Published

2024

21. Improving characterization of hypertrophy-induced murine cardiac dysfunction using four-dimensional ultrasound-derived strain mapping.

Author

Damen, Frederick W., Salvas, John P., Pereyra, Andrea S., Ellis, Jessica M., and Goergen, Craig J.

Subjects

*HEART diseases, *CARDIAC hypertrophy, *HEART failure, *CARNITINE palmitoyltransferase, *LABORATORY mice

Abstract

Mouse models of cardiac disease have become essential tools in the study of pathological mechanisms, but the small size of rodents makes it challenging to quantify heart function with noninvasive imaging. Building off recent developments in high-frequency four-dimensional ultrasound (4DUS) imaging, we have applied this technology to study cardiac dysfunction progression in a murine model of metabolic cardiomyopathy. Cardiac knockout of carnitine palmitoyltransferase 2 (Cpt2M-/-) in mice hinders cardiomyocyte bioenergetic metabolism of long-chain fatty acids, and leads to progressive cardiac hypertrophy and heart failure. The proposed analysis provides a standardized approach to measure localized wall kinematics and simultaneously extracts metrics of global cardiac function, LV morphometry, regional circumferential strain, and regional longitudinal strain from an interpolated 4-D mesh of the endo- and epicardial boundaries. Comparison of metric changes due to aging suggests that circumferential strain at the base and longitudinal strain along the posterior wall are most sensitive to disease progression. We further introduce a novel hybrid strain index (HSI) that incorporates information from these two regions and may have greater utility to characterize disease progression relative to other extracted metrics. Potential applications to additional disease models are discussed that could further demonstrate the utility of metrics derived from 4DUS imaging and strain mapping. [ABSTRACT FROM AUTHOR]

Published

2021

22. A novel particle-filled carbon-fibre reinforced polymer model composite tailored for the application of digital volume correlation and computed tomography.

Author

Schöberl, E, Breite, C, Rosini, S, Swolfs, Y, Mavrogordato, MN, Sinclair, I, and Spearing, SM

Subjects

*COMPUTED tomography, *DIGITAL image correlation, *SYNCHROTRON radiation, *BARIUM titanate, *MATERIALS analysis, *DISPLACEMENT (Mechanics)

Abstract

This paper presents the development of novel Carbon-Fibre Reinforced Polymer (CFRP) laminates, tailored for the application of Digital Volume Correlation (DVC) and Computed Tomography (CT) to experimental mechanics analyses of these materials. Analogous to surface-based Digital Image Correlation (DIC), DVC is a relatively novel volumetric method that utilizes CT data to quantify internal three-dimensional (3D) displacements and implicit strain fields. The highly anisotropic and somewhat regular/self-similar microstructures found in well-aligned unidirectional (UD) materials at high fibre volume fractions are intrinsically challenging for DVC, especially along the fibre direction at microstructural length-scales on the order of a few fibre diameters. To permit the application of DVC to displacement and/or strain measurements parallel to the fibre orientation, the matrix was doped with a sparse population of sub-micrometre particles to act as displacement trackers (i.e. fiducial markers). Barium titanate particles (400 nm, ∼1.44 vol. %) were found to offer the most favourable compromise between contrast in CT images and the ability to obtain a homogeneous distribution in 3D space with sufficient particle compactness for local DVC analyses. This property combination was selected following an extensive Micro-focus Computed Tomography (µCT)-based qualitative assessment on a wide test matrix, that included 38 materials manufactured with a range of possible particle compositions, mean sizes and concentrations. By comparing the tensile behaviour of the particle-adapted material alongside its particle-free counterpart, we demonstrate through the application of in situ Synchrotron Radiation Computed Tomography (SRCT) that the macro- and micromechanical responses of the newly developed CFRP are consistent with standard production materials indicating its suitability as a model system for mechanistic investigations. [ABSTRACT FROM AUTHOR]

Published

2021

23. Novel Elastography-Inspired Approach to Angiographic Visualization in Optical Coherence Tomography

Author

Alexey A. Zykov, Alexander L. Matveyev, Lev A. Matveev, Dmitry V. Shabanov, and Vladimir Y. Zaitsev

Subjects

optical coherence angiography, OCA, optical coherence elastography, strain mapping, blood vessels, contrasts-agent-free angiography, Applied optics. Photonics, TA1501-1820

Abstract

In this paper, we present a new approach to contrast-agent-free angiographic visualization in optical coherence tomography (OCT). The proposed approach has much in common with imaging of local interframe strains in OCT-based elastography and utilizes the fact that the interframe motion of blood particles leads to discontinuity of strains within the vessel cross section. By this reasoning, we call this approach “elastography-inspired”. Here, we first elucidate the essence and main features of the elastography-inspired approach using numerical simulation of OCT data. The simulations allow one to introduce both moving scatterers imitating blood flow in vessels as well as various masking motions imitating natural motions of living “solid” tissue surrounding the vessels. Second, using real OCT signals, we present comparative results of angiographic processing using the proposed elastography-inspired approach and a realization of OCA based on high-pass filtering of temporal variability of a series of OCT B-scans. The two methods can use the same initial dataset and the high-pass filtering OCA has already been routinely applied in both animal experiments and on patients. The new elastography-inspired method has a similar computational efficiency, and it is intrinsically able to compensate spatially-inhomogeneous masking tissue motions and demonstrates high robustness with respect to motion artefacts. Thus, the new approach looks very promising for enabling wider application of OCA in both laboratory studies on animals and, most importantly, for wider clinical applications on patients.

Published

2022

24. DIC-aided analysis of the fatigue behaviour of a welded 316L stainless steel

Author

Sriba, Amina, Bouquerel, Jérémie, and Vogt, Jean-Bernard

Published

2022

25. Annealing of focused ion beam damage in gold microcrystals: an in situ Bragg coherent X‐ray diffraction imaging study.

Author

Yang, David, Phillips, Nicholas W., Song, Kay, Harder, Ross J., Cha, Wonsuk, and Hofmann, Felix

Subjects

*FOCUSED ion beams, *X-ray imaging, *X-ray diffraction, *DIAGNOSTIC imaging, *GOLD, *THERMAL resistance

Abstract

Focused ion beam (FIB) techniques are commonly used to machine, analyse and image materials at the micro‐ and nanoscale. However, FIB modifies the integrity of the sample by creating defects that cause lattice distortions. Methods have been developed to reduce FIB‐induced strain; however, these protocols need to be evaluated for their effectiveness. Here, non‐destructive Bragg coherent X‐ray diffraction imaging is used to study the in situ annealing of FIB‐milled gold microcrystals. Two non‐collinear reflections are simultaneously measured for two different crystals during a single annealing cycle, demonstrating the ability to reliably track the location of multiple Bragg peaks during thermal annealing. The thermal lattice expansion of each crystal is used to calculate the local temperature. This is compared with thermocouple readings, which are shown to be substantially affected by thermal resistance. To evaluate the annealing process, each reflection is analysed by considering facet area evolution, cross‐correlation maps of the displacement field and binarized morphology, and average strain plots. The crystal's strain and morphology evolve with increasing temperature, which is likely to be caused by the diffusion of gallium in gold below ∼280°C and the self‐diffusion of gold above ∼280°C. The majority of FIB‐induced strains are removed by 380–410°C, depending on which reflection is being considered. These observations highlight the importance of measuring multiple reflections to unambiguously interpret material behaviour. [ABSTRACT FROM AUTHOR]

Published

2021

26. Strain and elasticity imaging in compression optical coherence elastography: The two‐decade perspective and recent advances.

Author

Zaitsev, Vladimir Y., Matveyev, Alexander L., Matveev, Lev A., Sovetsky, Alexander A., Hepburn, Matt S., Mowla, Alireza, and Kennedy, Brendan F.

Abstract

Quantitative mapping of deformation and elasticity in optical coherence tomography has attracted much attention of researchers during the last two decades. However, despite intense effort it took ~15 years to demonstrate optical coherence elastography (OCE) as a practically useful technique. Similarly to medical ultrasound, where elastography was first realized using the quasi‐static compression principle and later shear‐wave‐based systems were developed, in OCE these two approaches also developed in parallel. However, although the compression OCE (C‐OCE) was proposed historically earlier in the seminal paper by J. Schmitt in 1998, breakthroughs in quantitative mapping of genuine local strains and the Young's modulus in C‐OCE have been reported only recently and have not yet obtained sufficient attention in reviews. In this overview, we focus on underlying principles of C‐OCE; discuss various practical challenges in its realization and present examples of biomedical applications of C‐OCE. The figure demonstrates OCE‐visualization of complex transient strains in a corneal sample heated by an infrared laser beam. [ABSTRACT FROM AUTHOR]

Published

2021

27. Noncontact spatiotemporal strain mapping of composite multiferroic cylinders.

Author

Newacheck, Scott and Youssef, George

Abstract

Recently, the reinvigoration of research interest in in strain-mediated composite multiferroic structures resulted in translational magnetoelectric devices with superior performance than their traditional counterparts. Full-filed measurements and visualization of mechanical strain, with a focus at the interface, offer new possibilities for the advancement of magnetoelectric devices regardless of the material system. Here, we report spatiotemporal strain maps of composite magnetoelectric cylinders using a novel approach combining stable laser ultrasonic vibrometer and 2D motion system measurement technique. The physical measurement technique is augmented with a robust analysis algorithm that capable of effectively and consistently detect the interface. With the spatiotemporal maps, we forecast additional utility through the concurrent extraction of polarization and magnetization maps; hence highlighting the complex interactions between the involved order parameters. Understanding the converse magnetoelectric response in strain-mediated composite multiferroics is essential for the development of devices such and motors, antennas, and wireless power transferors. Given the dependence of the converse magnetoelectric response on the strain generation and transduction, mapping the mechanical response is essential for advancement of efficient devices. This mapping approach is challenging due to the dynamic nature of the response as well as the magneto-electro-mechanical coupling. Spatiotemporal maps of in-plane and out-of plane displacement and strain components were measured concurrently off the surface of a composite structure. To generate spatiotemporal strain maps, a laser-ultrasonic vibrometer mounted on a 2D gantry system was employed to map the in-plane and out-of-plane displacement components of a strain-mediated, concentric multiferroic composite cylinder. The strain maps provided insights on the behavior of the strain mediation mechanisms within the investigated composite structure including amplification of the strain due to the disparity in the mechanical properties of the constituents, which will result in a non-uniform distribution of magnetization and polarization responses. Additionally, the method to calculate the strain maps was shown to be robust for different spatial measurement resolutions. [ABSTRACT FROM AUTHOR]

Published

2020

28. Impact of krypton irradiation on a single crystal tungsten: Multi-modal X-ray imaging study.

Author

Gill, Simerjeet K., Topsakal, Mehmet, Jossou, Ericmoore, Huang, Xiaojing, Hattar, Khalid, Mausz, Julia, Elbakhshwan, Mohamed, Yan, Hanfei, Chu, Yong S., Sun, Cheng, He, Lingfeng, Gan, Jian, and Ecker, Lynne

Subjects

*SINGLE crystals, *X-ray imaging, *SYNCHROTRONS, *KRYPTON, *ELECTRON microscope techniques, *DIAGNOSTIC imaging

Abstract

Understanding microstructural and strain evolutions induced by noble gas production in the nuclear fuel matrix or plasma-facing materials is crucial for designing next generation nuclear reactors, as they are responsible for volumetric swelling and catastrophic failure. We describe a multimodal approach combining synchrotron-based nanoscale X-ray imaging techniques with atomic-scale electron microscopy techniques for mapping chemical composition, morphology and lattice distortion in a single crystal W induced by Kr irradiation. We report that Kr-irradiated single crystal W undergoes surface deformation, forming Kr containing cavities. Furthermore, positive strain fields are observed in Kr-irradiated regions, which lead to compression of underlying W matrix. Image, graphical abstract [ABSTRACT FROM AUTHOR]

Published

2020

29. High resolution strain mapping of a single axially heterostructured nanowire using scanning X-ray diffraction.

Author

Hammarberg, Susanna, Dagytė, Vilgailė, Chayanun, Lert, Hill, Megan O., Wyke, Alexander, Björling, Alexander, Johansson, Ulf, Kalbfleisch, Sebastian, Heurlin, Magnus, Lauhon, Lincoln J., Borgström, Magnus T., and Wallentin, Jesper

Abstract

Axially heterostructured nanowires are a promising platform for next generation electronic and optoelectronic devices. Reports based on theoretical modeling have predicted more complex strain distributions and increased critical layer thicknesses than in thin films, due to lateral strain relaxation at the surface, but the understanding of the growth and strain distributions in these complex structures is hampered by the lack of high-resolution characterization techniques. Here, we demonstrate strain mapping of an axially segmented GaInP-InP 190 nm diameter nanowire heterostructure using scanning X-ray diffraction. We systematically investigate the strain distribution and lattice tilt in three different segment lengths from 45 to 170 nm, obtaining strain maps with about 10−4 relative strain sensitivity. The experiments were performed using the 90 nm diameter nanofocus at the NanoMAX beamline, taking advantage of the high coherent flux from the first diffraction limited storage ring MAX IV. The experimental results are in good agreement with a full simulation of the experiment based on a three-dimensional (3D) finite element model. The largest segments show a complex profile, where the lateral strain relaxation at the surface leads to a dome-shaped strain distribution from the mismatched interfaces, and a change from tensile to compressive strain within a single segment. The lattice tilt maps show a cross-shaped profile with excellent qualitative and quantitative agreement with the simulations. In contrast, the shortest measured InP segment is almost fully adapted to the surrounding GaInP segments. [ABSTRACT FROM AUTHOR]

Published

2020

30. Fibre direction strain measurement in a composite ply under pure bending using Digital Volume Correlation and Micro-focus Computed Tomography.

Author

Schöberl, Erich, Mavrogordato, MN, Sinclair, I, and Spearing, SM

Subjects

*COMPUTED tomography, *EULER-Bernoulli beam theory, *FIBERS, *SPATIAL filters, *TIMOSHENKO beam theory, *ANALYTICAL solutions, *DISPLACEMENT (Mechanics)

Abstract

This paper presents an experimental demonstration and validation of high-resolution three-dimensional experimental strain measurement using Digital Volume Correlation (DVC) on Carbon Fibre-Reinforced Polymers, via through-thickness strain analysis under a state of pure bending. To permit the application of DVC to displacements and/or strain measurements parallel to the fibre direction in well-aligned unidirectional materials at high volume fractions, a methodology was developed for the insertion of sparse populations of 400 nm BaTiO3 particles within the matrix to act as displacement trackers (i.e. fiducial markers). For this novel material system, measurement sensitivity and noise are considered, along with the spatial filtering intrinsic to established DVC data processing. In conjunction with Micro-focus Computed Tomography, the technique was applied to a simple standard specimen subjected to a four-point flexural test, which resulted in a linear strain distribution through the beam thickness. The high-resolution, fibre-level strain distributions (imaged at a voxel resolution of ∼0.64 µm) were compared against the classical beam theory (Euler–Bernoulli) in incrementally decreasing averaging schemes and different sub-set sizes. Different sampling and averaging strategies are reported, showing that DVC outputs can be obtained that are in very good agreement with the analytical solution. A practical lower limit for the spatial resolution of strain is discerned for the present materials and methods. This study demonstrates the effectiveness of DVC in measuring local strains parallel to the fibre direction, with corresponding potential for calibration and validation of micromechanical models predicting various fibre-dominated damage mechanisms. [ABSTRACT FROM AUTHOR]

Published

2020

31. Characterization and application of Bragg‐edge transmission imaging for strain measurement and crystallographic analysis on the IMAT beamline.

Author

Ramadhan, Ranggi S., Kockelmann, Winfried, Minniti, Triestino, Chen, Bo, Parfitt, David, Fitzpatrick, Michael E., and Tremsin, Anton S.

Subjects

*CRYSTALLOGRAPHY, *STRAINS & stresses (Mechanics), *IMAGING systems, *CRYSTAL texture, *ALLOYS, *BRAGG gratings

Abstract

This paper presents a series of experiments to characterize the performance of the new IMAT beamline at the ISIS pulsed neutron source and provides examples to showcase the potential applications of Bragg‐edge transmission imaging on the instrument. The characterization includes determination of the IMAT spectral and spatial resolutions through calibration measurements, and also determination of the precision and the accuracy of Bragg‐edge analysis for lattice parameters of ceramics, metals and textured engineering alloys through high‐temperature measurements. A novel Bragg‐edge analysis method based on the cross‐correlation of different Bragg edges has been developed to provide an estimate of the change in lattice parameter, which is especially useful for measurements of textured samples. Three different applications of the Bragg‐edge transmission imaging technique are presented, including strain mapping, texture mapping and obtaining crystallographic information, i.e. the dependence on temperature of the Debye–Waller factor. The experimental results demonstrate the ability of the IMAT beamline to provide accurate strain measurements with uncertainties as low as 90 µϵ with reasonable measurement time, while characteristic materials parameters can be mapped across the sample with a spatial resolution of 300–600 µm for a strain map and down to ∼90 µm for a texture map. Characterization of Bragg‐edge transmission imaging on the new IMAT beamline at the ISIS pulsed neutron source is performed and application of the technique is demonstrated. Bragg‐edge transmission is capable of producing accurate strain maps with high spatial resolution and spatially resolved texture information, non‐destructively. [ABSTRACT FROM AUTHOR]

Published

2019

32. Joint non-rigid image registration and reconstruction for quantitative atomic resolution scanning transmission electron microscopy.

Author

Berkels, Benjamin and Liebscher, Christian H.

Subjects

*IMAGE reconstruction, *IMAGE registration, *SCANNING transmission electron microscopy, *IMAGE processing, *ATOMS, *TRANSMISSION electron microscopes

Abstract

Highlights • Novel bias-corrected non-rigid registration approach compensating for fast and slow scan artifacts in scanning transmission electron microscopes (STEM) image series. • Bias-correction responsible for the correction of the slow scan artifacts. • Reduces fast scan noise in an image series and slow scan distortions simultaneously. • Tested on synthetic and experimental images. Abstract Aberration corrected scanning transmission electron microscopes (STEM) enable to determine local strain fields, composition and bonding states at atomic resolution. The precision to locate atomic columns is often obstructed by scan artifacts limiting the quantitative interpretation of STEM datasets. Here, a novel bias-corrected non-rigid registration approach is presented that compensates for fast and slow scan artifacts in STEM image series. The bias-correction is responsible for the correction of the slow scan artifacts and based on a explicit coupling of the deformations of the individual images in a series via a minimization of the average deformation. This allows to reduce fast scan noise in an image series and slow scan distortions simultaneously. The novel approach is tested on synthetic and experimental images and its implication on atomic resolution strain and elemental mapping is discussed. [ABSTRACT FROM AUTHOR]

Published

2019

33. A demonstration of the mechanical sensing capability of individually contacted vertical piezoelectric nanowires arranged in matrices.

Author

Parmar, Mitesh, Leon Perez, Edgar A.A., Ardila, Gustavo, Saoutieff, Elise, Pauliac-Vaujour, Emmanuelle, and Mouis, Mireille

Abstract

Abstract This paper reports the fabrication of arrays of vertical piezoelectric nanowires which are individually contacted at their base, and demonstrates that an electrical response to strain can be obtained from individual nanowires from the array, without external biasing exploiting the piezotronic effect. Such a technology could thus be used for the fabrication of self-powered sensors for mechanical strain mapping, where each individually contacted nanowire would act as the strain sensing equivalent of a pixel. Lateral mapping resolutions in the micrometer range can be obtained. Here, the hydrothermal method was used to grow vertical ZnO nanowires selectively between two electrodes that had been patterned beforehand. For the sake of demonstration, nanowires deflection was produced by subjecting the array of nanowires to an incident lateral gas flow of controlled rate, which was switched on and off repeatedly across the sample while electrical response was measured. Different experimental configurations were tested in terms of flow rate, flow orientation, or nanowire position with respect to tube outlet. Experiments were carried out with compressed nitrogen and air. The experimental results are fully consistent with the piezoelectric and piezotronic response which can be expected with this geometry. Moreover, it is shown that the electrical response under nitrogen flow is a linear function of flow rate and that its sign provides information about flow direction. These results demonstrate the very promising prospects of this new technology for high-resolution mapping, with potential applications in gas or liquid flow sensing, fingerprints detection or human-machine interfaces. Graphical abstract fx1 Highlights • Experimental demonstration of individually contacted vertical ZnO NWs based sensors. • The fabrication used is large scale compatible and allows the matrices arrangement. • Results show a linear response with flow rate and consistent with orientation. • It exhibits prospect for high-resolution mapping of force/ deformation distribution. [ABSTRACT FROM AUTHOR]

Published

2019

34. Importance of TEM sample thickness for measuring strain fields.

Author

Kang, Sangjun, Wang, Di, Kübel, Christian, and Mu, Xiaoke

Subjects

*METALLIC glasses, *MULTIPLE scattering (Physics), *TRANSMISSION electron microscopy, *SPATIAL resolution

Abstract

• Residual strain in deformed metallic glasses is reduced during the thinning process. • FIB thinning induces structural change by a combination of surface relaxation and damage from ion irradiations. • A thickness of around 200 nm best compromises between data quality in 4D-STEM and maintaining the strain distribution. • Too strong sample thinning prevents the preservation of the native deformation structure of metallic glasses. Transmission electron microscopy (TEM) has emerged as a valuable tool for assessing and mapping strain fields within materials. By directly analyzing local atomic spacing variations, TEM enables the precise measurement of local strain with high spatial resolution. However, it is standard practice to use thin specimens in TEM analysis to ensure electron transparency and minimize issues such as projection artifacts and contributions from multiple scattering. This raises an important question regarding the extent of structural modification, such as strain relaxation, induced in thin samples due to the increased surface-to-volume ratio and the thinning process. In this study, we conducted a systematic investigation to quantify the influence of TEM sample thickness on the residual strain field using deformed Fe-based and Zr-based metallic glasses as model systems. The samples were gradually thinned from 300 nm to 70 nm, and the same area was examined using 4D-STEM with identical imaging settings. Our results demonstrate that thinning the sample affects the atomic configuration at both the short-range (SR) and medium-range (MR) scales. Consequently, when the sample is thinned too much, it no longer preserves the native deformation structure. These findings highlight the critical importance of maintaining sufficient TEM sample thickness for obtaining meaningful and accurate strain measurements. [ABSTRACT FROM AUTHOR]

Published

2024

35. In-situ measurement of dynamic micro X-ray CT and dynamic mechanical analysis for rubber materials.

Author

Matsubara, Masami, Takara, Ryo, Komatsu, Taichi, Furuta, Shogo, Pei Loon, Khoo, Kobayashi, Masakazu, Mushiaki, Hitomu, Uesugi, Kentaro, Kawamura, Shozo, and Tajiri, Daiki

Subjects

*DYNAMIC mechanical analysis, *MATERIALS analysis, *STRAINS & stresses (Mechanics), *COMPUTED tomography, *MECHANICAL behavior of materials, *RUBBER

Abstract

Observing the internal state that takes place during deformation is essential for comprehending the mechanical properties of polymeric materials like rubber. For the effective utilization of rubber in damping applications, it is imperative to comprehend the relationship between the loss factor and microstructure. In an earlier study, we developed a dynamic X-ray CT technique tailored for damping materials subjected to tensile amplitude and proposed a method to directly evaluate the internal deformation behavior under dynamic conditions. However, owing to the technical constraints of the shaker employed for dynamic X-ray computed tomography, key variables such as vibration frequency and amplitude could not be incorporated into the analysis. Additionally, it has not been possible to simultaneously measure dynamic viscoelasticity and dynamic micro X-ray CT in situ. In this study, we developed an experimental system that enables simultaneous measurement of dynamic mechanical properties and dynamic X-ray computed tomography (CT). This system facilitates in-situ investigation of internal deformation behavior and the loss factor in rubber materials, allowing for the assessment of variations in loss factors at the micro-scale. We examined the differences between styrene butadiene rubber (SBR) and natural rubber (NR) as base materials and investigated the influence of shape, and particle size of ZnO on the dynamic behavior of SBR composites. Dynamic X-ray computed tomography (CT) was conducted at excitation frequencies of 1 and 2 Hz, excitation amplitudes corresponding to 1% and 1.25% of the inter-chuck distance of the specimens, and a spatial resolution of 0.5 µm. Local strains were extracted from the 3D reconstructed images, and both the local strain amplitudes and their histograms were assessed as characteristics of dynamic behavior. The results indicated that the effect of varying the excitation frequency between 1 and 2 Hz was minimal for the SBR. Additionally, the median value of local strain amplitudes shifted in relation to the magnitude of the excitation amplitude. When comparing base materials (SBR and NR) with significantly different loss factors, no discernible differences were observed in the histograms of local strain amplitudes. The histograms did vary based on the formulation conditions of the SBR microparticle composite, although the loss factor remained unchanged. This lack of change in the loss factor can be attributed to the minimal impact of the particulate composites on the inherent loss factor of pure SBR. Importantly, the study successfully achieved multimodal and simultaneous measurements using dynamic mechanical analysis and dynamic micro X-ray CT. [ABSTRACT FROM AUTHOR]

Published

2023

36. Interstitial Nature of Mn2+ Doping in 2D Perovskites

Author

Andrew J. Torma, Wenbin Li, Hao Zhang, Qing Tu, Vladislav V. Klepov, Michael C. Brennan, Christopher L. McCleese, Matthew D. Krzyaniak, Michael R. Wasielewski, Claudine Katan, Jacky Even, Martin V. Holt, Tod A. Grusenmeyer, Jie Jiang, Ruth Pachter, Mercouri G. Kanatzidis, Jean-Christophe Blancon, Aditya D. Mohite, Rice University [Houston], Texas A&M University [College Station], Northwestern University [Evanston], Air Force Research Laboratory (AFRL), United States Air Force (USAF), Institut des Sciences Chimiques de Rennes (ISCR), Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Ecole Nationale Supérieure de Chimie de Rennes (ENSCR)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), Institut National des Sciences Appliquées (INSA)-Université de Rennes (UNIV-RENNES)-Institut National des Sciences Appliquées (INSA), Institut des Fonctions Optiques pour les Technologies de l'informatiON (Institut FOTON), Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), Institut National des Sciences Appliquées (INSA)-Université de Rennes (UNIV-RENNES)-Institut National des Sciences Appliquées (INSA)-École Nationale Supérieure des Sciences Appliquées et de Technologie (ENSSAT)-Centre National de la Recherche Scientifique (CNRS)-IMT Atlantique Bretagne-Pays de la Loire (IMT Atlantique), Institut Mines-Télécom [Paris] (IMT)-Institut Mines-Télécom [Paris] (IMT), Argonne National Laboratory [Lemont] (ANL), Université de Rennes (UR)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Ecole Nationale Supérieure de Chimie de Rennes (ENSCR)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-École Nationale Supérieure des Sciences Appliquées et de Technologie (ENSSAT)-Centre National de la Recherche Scientifique (CNRS), FA8650-16-D-5402-0001, Air Force Research Laboratory, Army Research Office, DE-FG02-99ER14999, Basic Energy Sciences, Texas A and M Engineering Experiment Station, Texas A and M University, Institut Universitaire de France, 20-587, National Science Foundation, and Triads for Transformation, Texas A and M University

Subjects

[PHYS]Physics [physics], crystal structure, strain mapping, General Engineering, General Physics and Astronomy, doping, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, nano X-ray diffraction, 01 natural sciences, transition metals, 0104 chemical sciences, Condensed Matter::Materials Science, halide perovskites, [CHIM]Chemical Sciences, Condensed Matter::Strongly Correlated Electrons, General Materials Science, 0210 nano-technology, density functional theory, ComputingMilieux_MISCELLANEOUS

Abstract

International audience; Halide perovskites doped with magnetic impurities (such as the transition metals Mn2+, Co2+, Ni2+) are being explored for a wide range of applications beyond photovoltaics, such as spintronic devices, stable light-emitting diodes, single-photon emitters, and magneto-optical devices. However, despite several recent studies, there is no consensus on whether the doped magnetic ions will predominantly replace the octahedral B-site metal via substitution or reside at interstitial defect sites. Here, by performing correlated nanoscale X-ray microscopy, spatially and temporally resolved photoluminescence measurements, and magnetic force microscopy on the inorganic 2D perovskite Cs2PbI2Cl2, we show that doping Mn2+ into the structure results in a lattice expansion. The observed lattice expansion contrasts with the predicted contraction expected to arise from the B-site metal substitution, thus implying that Mn2+ does not replace the Pb2+ sites. Photoluminescence and electron paramagnetic resonance measurements confirm the presence of Mn2+ in the lattice, while correlated nano-XRD and X-ray fluorescence track the local strain and chemical composition. Density functional theory calculations predict that Mn2+ atoms reside at the interstitial sites between two octahedra in the triangle formed by one Cl– and two I– atoms, which results in a locally expanded structure. These measurements show the fate of the transition metal dopants, the local structure, and optical emission when they are doped at dilute concentrations into a wide band gap semiconductor.

Published

2021

37. Flexible Li-doped ZnO piezotronic transistor array for in-plane strain mapping.

Author

Song, Ming, Liu, Yudong, Yu, Aifang, Zhang, Yang, Zhai, Junyi, and Wang, Zhong Lin

Abstract

Abstract Thin film is a good choice for in-plane strain sensing and is also technical compatible with modern electronic industry. In this paper, a thin film based piezotronic transistors array was demonstrated for the first time. The piezotronic effect of the sensing units was investigated and qualitative characterized. The strain sensitivity (gauge factor) of the units was derived up to 199, which is around 100 times of the sensitivity of the commercial foil gauge. After calibration on every sensing unit, the distribution of the strain applied on the device was successfully measured and mapped by the sensor array, which show the big potential of the thin film based piezotronic transistors array on the application of high space resolution, high sensitivity field deformation sensing. Graphical abstract fx1 Highlights • Li-doped ZnO shows better strain-tuned I-V characteristic than un-doped ZnO due to the decrease of screening effect. • The in-plane strain sensor based on Li-doped ZnO is 100 times more sensitive than that of the commercial foil gauge. • A high spatial resolution in-plane strain sensor array has fabricated by using Li-doped ZnO film. [ABSTRACT FROM AUTHOR]

Published

2019

38. In-situ evaluation of C/SiC composites via an ultraviolet imaging system and microstructure based digital image correlation.

Author

Dong, Yali

Subjects

*CARBON fibers, *CARBON fiber-reinforced ceramics, *SILICON carbide, *CARBIDES, *MICROSTRUCTURE

Abstract

Carbon fibre reinforced silicon carbide (C/SiC) composites were in situ observed up to 1400°C using an ultraviolet (UV) imaging system. The captured images were analysed by mean grey values at different temperatures. Thermal strain fields were obtained via digital image correlation (DIC) using the microstructure as speckle patterns (microstructure based DIC, M-DIC). The results show that it was effective using UV imaging system for in situ observation of surface of C/SiC composite up to 1400°C. Below 1000°C, the C/SiC kept no change while above 1000°C the change of SiC occurred. Local strain showed heterogeneous values based on the microstructure of C/SiC. The averaged coefficient of thermal expansion of cabon fibre bundles in composite measured agreed well with the literature data. [ABSTRACT FROM AUTHOR]

Published

2018

39. Microscale frictional strains determine chondrocyte fate in loaded cartilage.

Author

Bonnevie, Edward D., Delco, Michelle L., Bartell, Lena R., Jasty, Naveen, Cohen, Itai, Fortier, Lisa A., and Bonassar, Lawrence J.

Subjects

*FRICTION, *CARTILAGE cells, *MITOCHONDRIA, *SHEAR strain, *TREATMENT of arthritis

Abstract

Mounting evidence suggests that altered lubricant levels within synovial fluid have acute biological consequences on chondrocyte homeostasis. While these responses have been connected to increased friction, the mechanisms behind this response remain unknown. Here, we combine a frictional bioreactor with confocal elastography and image-based cellular assays to establish the link between cartilage friction, microscale shear strain, and acute, adverse cellular responses. Our incorporation of cell-scale strain measurements reveals that elevated friction generates high shear strains localized near the tissue surface, and that these elevated strains are closely associated with mitochondrial dysfunction, apoptosis, and cell death. Collectively, our data establish two pathways by which chondrocytes negatively respond to friction: an immediate necrotic response and a longer term pathway involving mitochondrial dysfunction and apoptosis. Specifically, in the surface region, where shear strains can exceed 0.07, cells are predisposed to acute death; however, below this surface region, cells exhibit a pathway consistent with apoptosis in a manner predicted by local shear strains. These data reveal a mechanism through which cellular damage in cartilage arises from compromised lubrication and show that in addition to boundary lubricants, there are opportunities upstream of apoptosis to preserve chondrocyte health in arthritis therapy. [ABSTRACT FROM AUTHOR]

Published

2018

40. Multiscale analysis of nanoindentation-induced defect structures in gum metal.

Author

Sankaran, R.P., Ozdol, V.B., Ophus, C., Kacher, J., Gammer, C., Govindjee, S., Minor, A.M., and Jr.Morris, J.W.

Subjects

*METALS, *NANOPARTICLES, *MINERALS, *NANOSTRUCTURED materials, *SHEAR (Mechanics)

Abstract

Using ex-situ transmission electron microscopy and the recently developed nanoprobe diffraction (NPD) technique, we characterize a nanoindented solution treated gum metal. Lattice rotations are resolved at a 1.2 nm length-scale and shown to be continuous within the nanoindentation pit; further, it is shown that these can be accommodated by a reasonable number of geometrically necessary dislocations at a density of ∼10 15 /m 2 . We additionally provide direct evidence that dislocations within the nanoindent, rather than secondary phase nanoparticles, can serve as potent barriers to dislocation motion. We also demonstrate that plasticity in these alloys under nanoindentation can be accommodated solely by dislocation nucleation and propagation, with no competing deformation mechanisms present. Conventional transmission electron microscopy and “ g•b ” analysis reveal the presence of dislocations on 〈 1 ¯ 11 〉 {110} slip systems and highly localized plastic deformation in the form of shear bands on <111> { 1 ¯ 1 ¯ 2 } slip systems, similar to previously observed “giant faults”. [ABSTRACT FROM AUTHOR]

Published

2018

41. Reduction of Thermal Conductivity in Nanowires by Combined Engineering of Crystal Phase and Isotope Disorder.

Author

Mukherjee, S., Givan, U., Senz, S., de la Mata, M., Arbiol, J., and Moutanabbir, O.

Subjects

*THERMAL conductivity, *NANOWIRES, *ISOTOPES, *PHASE transitions, *HEAT transfer

Abstract

Nanowires are a versatile platform to investigate and harness phonon and thermal transport phenomena in nanoscale systems. With this perspective, we demonstrate herein the use of crystal phase and mass disorder as effective degrees of freedom to manipulate the behavior of phonons and control the flow of local heat in silicon nanowires. The investigated nanowires consist of isotopically pure and isotopically mixed nanowires bearing either a pure diamond cubic or a cubic-rhombohedral polytypic crystal phase. The nanowires with tailor-made isotopic compositions were grown using isotopically enriched silane precursors 28SiH4, 29SiH4, and 30SiH4 with purities better than 99.9%. The analysis of polytypic nanowires revealed ordered and modulated inclusions of lamellar rhombohedral silicon phases toward the center in otherwise diamond-cubic lattice with negligible interphase biaxial strain. Raman nanothermometry was employed to investigate the rate at which the local temperature of single suspended nanowires evolves in response to locally generated heat. Our analysis shows that the lattice thermal conductivity in nanowires can be tuned over a broad range by combining the effects of isotope disorder and the nature and degree of polytypism on phonon scattering. We found that the thermal conductivity can be reduced by up to ∼40% relative to that of isotopically pure nanowires, with the lowest value being recorded for the rhombohedral phase in isotopically mixed 28Six30Si1–x nanowires with composition close to the highest mass disorder (x ∼ 0.5). These results shed new light on the fundamentals of nanoscale thermal transport and lay the groundwork to design innovative phononic devices. [ABSTRACT FROM AUTHOR]

Published

2018

42. Mapping residual strain induced by cold working and by laser shock peening using neutron transmission spectroscopy.

Author

Ramadhan, Ranggi S., Syed, Abdul K., Tremsin, Anton S., Kockelmann, Winfried, Dalgliesh, Robert, Chen, Bo, Parfitt, David, and Fitzpatrick, Michael E.

Subjects

*STRAIN hardening, *NEUTRON transport theory, *ALUMINUM alloys, *BRAGG gratings, *MATHEMATICAL mappings

Abstract

This paper presents 2D mapping of residual strains, induced by cold expansion and laser shock peening processing of aluminium alloy samples, by using Bragg edge neutron transmission. Neutron transmission uses information contained in the neutron beam transmitted through a sample. It is shown that neutron transmission strain mapping with high spatial resolution can provide important insights into the distribution of residual strains associated with processing of materials. The residual strain field around a cold-expanded hole can be revealed in detail, as can be the residual strain profile associated with laser peening. Results are correlated with measurements obtained by conventional neutron diffraction and incremental hole drilling. The residual strain variation around the cold-expanded hole and the depth of compressive residual strain generated by the peening process were captured with high spatial resolution, showing the advantages of neutron transmission over other well-established strain measurement methods by non-destructively generating a map of residual strains over a large area. [ABSTRACT FROM AUTHOR]

Published

2018

43. Piezotronic analog-to-digital converters based on strain-gated transistors.

Author

Nie, Jiaheng, Hu, Gongwei, Li, Lijie, and Zhang, Yan

Abstract

We report a novel approach to achieve piezotronic analog-to-digital converters (ADCs) based on strain gated transistors (SGTs). A single SGT can act as voltage converter, comparator, and amplifier. The new piezotronic ADC devices benefit from high sensitivity of the piezotronic SGT responding to the external strains. This design can significantly reduce the power consumption and the size of these devices, which are considered as crucial factors in self-powered systems. The fundamental concept of the device design has been demonstrated by three piezotronic ADC architectures formed by various networks comprised of SGTs and resistors. Analog-to-digital conversion and logic operations of these piezotronic ADCs blocks are analyzed and logic truth tables for all those configurations are presented. This design has immense potential for enormous applications in future human-machine interfaces, internet of things, and sensor networks. [ABSTRACT FROM AUTHOR]

Published

2018

44. Atomic‐Strain Mapping of High‐Index Facets in Late‐Transition‐Metal Nanoparticles for Electrocatalysis

Author

Tong Wu, Mingzi Sun, and Bolong Huang

Subjects

Materials science, High index, Nanoparticle, Nanotechnology, Strain mapping, General Chemistry, General Medicine, Electrochemistry, Electrocatalyst, Catalysis, Nanomaterials, Metal, Transition metal, Ab initio quantum chemistry methods, Chemical physics, visual_art, visual_art.visual_art_medium

Abstract

Although high-index facets (HIF) endows excellent catalytic activity through undercoordinated sites with strain effect, current characterizations techniques still cannot unravel the detailed strain distributions to understand the origins of electroactivity. Nevertheless, theoretical principles to quantify the structural features and their effects on catalytic activity improvements on HIFs are still lacking, which renders the experimental efforts laborious. In this work, we explore the quantification of surface structural features and establish a database of atomic strain distributions for the late-transition metal HIF nanoparticle models. The surface reactivities of the nanoparticles have been examined by adsorption energy calculations and their correlations with structural features are observed. Our proposed theoretical principles on surface characterizations of high-index facets nanomaterials will promote the design and synthesis of efficient transition metal based electrocatalysts.

Published

2021

45. Practical obstacles and their mitigation strategies in compressional optical coherence elastography of biological tissues

Author

Vladimir Y. Zaitsev, Alexandr L. Matveyev, Lev A. Matveev, Ekaterina V. Gubarkova, Alexandr A. Sovetsky, Marina A. Sirotkina, Grigory V. Gelikonov, Elena V. Zagaynova, Natalia D. Gladkova, and Alex Vitkin

Subjects

Optical coherence elastography, optical coherence tomography, phase-resolved methods, strain mapping, stiffness characterization, Technology, Optics. Light, QC350-467

Abstract

In this paper, we point out some practical obstacles arising in realization of compressional optical coherence elastography (OCE) that have not attracted sufficient attention previously. Specifically, we discuss (i) complications in quantification of the Young modulus of tissues related to partial adhesion between the OCE probe and soft intervening reference layer sensor, (ii) distorting influence of tissue surface curvature/corrugation on the subsurface strain distribution mapping, (iii) ways of signal-to-noise ratio (SNR) enhancement in OCE strain mapping when periodic averaging is not realized, and (iv) potentially significant influence of tissue elastic nonlinearity on quantification of its stiffness. Potential practical approaches to mitigate the effects of these complications are also described.

Published

2017

46. Annealing of focused ion beam damage in gold microcrystals: an in situ Bragg coherent X-ray diffraction imaging study

Author

Ross Harder, Wonsuk Cha, Nicholas W. Phillips, Felix Hofmann, David Yang, and Kay Song

Subjects

Diffraction, Nuclear and High Energy Physics, strain mapping, Materials science, Physics::Instrumentation and Detectors, Annealing (metallurgy), Thermal resistance, Bragg coherent X-ray diffraction imaging, FOS: Physical sciences, Physics::Optics, chemistry.chemical_element, 02 engineering and technology, Focused ion beam, Crystal, 03 medical and health sciences, Gallium, Instrumentation, 030304 developmental biology, Condensed Matter - Materials Science, 0303 health sciences, Radiation, business.industry, Materials Science (cond-mat.mtrl-sci), cross-correlation, 021001 nanoscience & nanotechnology, Research Papers, facet growth, 3. Good health, Reflection (mathematics), chemistry, X-ray crystallography, Optoelectronics, annealing, 0210 nano-technology, business

Abstract

Focused ion beam (FIB) techniques are commonly used to machine, analyse and image materials at the micro- and nanoscale. However, FIB modifies the integrity of the sample by creating defects that cause lattice distortions. Methods have been developed to reduce FIB-induced strain, however these protocols need to be evaluated for their effectiveness. Here we use non-destructive Bragg coherent X-ray diffraction imaging to study the in situ annealing of FIB-milled gold microcrystals. We simultaneously measure two non-collinear reflections for two different crystals during a single annealing cycle, demonstrating the ability to reliably track the location of multiple Bragg peaks during thermal annealing. The thermal lattice expansion of each crystal is used to calculate the local temperature. This is compared to thermocouple readings, which are shown to be substantially affected by thermal resistance. To evaluate the annealing process, we analyse each reflection by considering facet area evolution, cross-correlation maps of displacement field and binarised morphology, and average strain plots. The crystal's strain and morphology evolve with increasing temperature, which is likely to be caused by the diffusion of gallium in gold below ~280{\deg}C and the self-diffusion of gold above ~280{\deg}C. The majority of FIB-induced strains are removed by 380-410\degree C, depending on which reflection is being considered. Our observations highlight the importance of measuring multiple reflections to unambiguously interpret material behaviour., Comment: 51 pages, 16 figures

Published

2021

47. EVALUATION OF THE NANOSTRAIN CAUSED BY INCOHERENT PARTICLES IN AN ALUMINUM-BASED COMPOSITE.

Author

Hernández-Rivera, J. L., Ramos-Azpeitia, M., Rivera, J. J. Cruz, Moreno, J. Palmerin, and Garay-Reyes, C. G.

Subjects

*ALUMINUM compounds, *METALLIC composites, *NANOSTRUCTURED materials, *GRAPHITE, *HIGH resolution electron microscopy

Abstract

Aluminium based composite with dispersed graphite particles was processed by means of mechanical alloying, cold compression, sintering and hot extrusion. Samples for High Resolution Electron Microscopy (HRTEM) were obtained from extruded bars and were prepared using ultrasonic cutting, mechanical grinding, jet electropolishing and ion milling. Significant strain gradients are created in the metal matrix composites because of thermal mismatch between matrix and reinforcement particles. The main objective of this work was to determine by HRTEM in a quantitative way, the strain gradients in the matrix, in order to be able to predict the increments in the flow stress and the modification in the precipitation kinetics in future works. The geometric phase analysis (GPA) technique was employed to measure strain in the vicinity of the graphite particles. In order to avoid commonly observed errors in strain maps generated from HRTEM images we applied the GPA technique to the exit face wave function reconstructed from a focal series of HRTEM micrographs. It was possible to establish that the matrix is subjected to tension strain gradients that extend out to about 5 nm around the graphite particles. It was observed that the strain in transverse direction (εxx) was higher than the longitudinal (εyy). According to the results obtained the strain was heterogeneous and had a maximum value of 2.2 % in areas close to the particles. [ABSTRACT FROM AUTHOR]

Published

2018

48. Practical obstacles and their mitigation strategies in compressional optical coherence elastography of biological tissues.

Author

Zaitsev, Vladimir Y., Matveyev, Alexandr L., Matveev, Lev A., Gubarkova, Ekaterina V., Sovetsky, Alexandr A., Sirotkina, Marina A., Gelikonov, Grigory V., Zagaynova, Elena V., Gladkova, Natalia D., and Vitkin, Alex

Subjects

TISSUE analysis, OPTICAL coherence tomography, STIFFNESS (Engineering), ELASTOGRAPHY, STRAIN energy

Abstract

In this paper, we point out some practical obstacles arising in realization of compressional optical coherence elastography (OCE) that have not attracted sufficient attention previously. Specifically, we discuss (i) complications in quantification of the Young modulus of tissues related to partial adhesion between the OCE probe and soft intervening reference layer sensor, (ii) distorting influence of tissue surface curvature/corrugation on the subsurface strain distribution mapping, (iii) ways of signal-to-noise ratio (SNR) enhancement in OCE strain mapping when periodic averaging is not realized, and (iv) potentially significant influence of tissue elastic nonlinearity on quantification of its stiffness. Potential practical approaches to mitigate the effects of these complications are also described. [ABSTRACT FROM AUTHOR]

Published

2017

49. Optical coherence elastography for strain dynamics measurements in laser correction of cornea shape.

Author

Zaitsev, Vladimir Y., Matveyev, Alexander L., Matveev, Lev A., Gelikonov, Grigory V., Omelchenko, Alexander I., Baum, Olga I., Avetisov, Sergey E., Bolshunov, Andrey V., Siplivy, Vladimir I., Shabanov, Dmitry V., Vitkin, Alex, and Sobol, Emil N.

Abstract

We describe the use of elastographic processing in phase-sensitive optical coherence tomography (OCT) for visualizing dynamics of strain and tissue-shape changes during laser-induced photothermal corneal reshaping, for applications in the emerging field of non-destructive and non-ablative (non-LASIK) laser vision correction. The proposed phase-processing approach based on fairly sparse data acquisition enabled rapid data processing and near-real-time visualization of dynamic strains. The approach avoids conventional phase unwrapping, yet allows for mapping strains even for significantly supra-wavelength inter-frame displacements of scatterers accompanied by multiple phase-wrapping. These developments bode well for real-time feedback systems for controlling the dynamics of corneal deformation with 10-100 ms temporal resolution, and for suitably long-term monitoring of resultant reshaping of the cornea. In ex-vivo experiments with excised rabbit eyes, we demonstrate temporal plastification of cornea that allows shape changes relevant for vision-correction applications without affecting its transparency. We demonstrate OCT's ability to detect achieving of threshold temperatures required for tissue plastification and simultaneously characterize transient and cumulative strain distributions, surface displacements, and scattering tissue properties. Comparison with previously used methods for studying laser-induced reshaping of cartilaginous tissues and numerical simulations is performed. [ABSTRACT FROM AUTHOR]

Published

2017

50. Accuracy of surface strain measurements from transmission electron microscopy images of nanoparticles.

Author

Madsen, Jacob, Liu, Pei, Wagner, Jakob, Hansen, Thomas, and Schiøz, Jakob

Subjects

NANOPARTICLES, TRANSMISSION electron microscopy, SURFACE strains, IMAGING systems in chemistry, OPTICAL aberrations

Abstract

Strain analysis from high-resolution transmission electron microscopy (HRTEM) images offers a convenient tool for measuring strain in materials at the atomic scale. In this paper we present a theoretical study of the precision and accuracy of surface strain measurements directly from aberration-corrected HRTEM images. We examine the influence of defocus, crystal tilt and noise, and find that absolute errors of at least 1-2% strain should be expected. The model structures include surface relaxations determined using molecular dynamics, and we show that this is important for correctly evaluating the errors introduced by image aberrations. [ABSTRACT FROM AUTHOR]

Published

2017