Micron-scale crack propagation in laser-irradiated enamel and dentine studied with nano-CT

Aljdaimi, Abtesam; Devlin, Hugh; Dickinson, Mark; Burnett, Timothy L.; Slater, Thomas J. A.

doi:10.1007/s00784-018-2654-0

Cited by 14 publications

(10 citation statements)

References 23 publications

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“…Hard tissues have been extensively studied using micro-CT [10][11][12][13], though this technique is limited to micron resolution. Nanoscale resolution of dental structures has more recently been made possible with nano-CT; however, this technique requires specific instruments, a synchrotron X-ray source, or special sample preparation, which has limited its utility for studying intricate structures [14][15][16][17][18][19][20]. Atomic force microscopy is also an advanced tool for dental research as it can provide high-resolution images and reveal mechanical properties [21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

Applications of scanning electron microscopy and focused ion beam milling in dental research

House

Long

O’Carroll

et al. 2022

European J Oral Sciences

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The abilities of scanning electron microscopy (SEM) and focused ion beam (FIB) milling for obtaining high-resolution images from top surfaces, cross-sectional surfaces, and even in three dimensions, are becoming increasingly important for imaging and analyzing tooth structures such as enamel and dentin. FIB was originally developed for material research in the semiconductor industry. However, use of SEM/FIB has been growing recently in dental research due to the versatility of dual platform instruments that can be used as a milling device to obtain low-artifact cross-sections of samples combined with high-resolution images. The advent of the SEM/FIB system and accessories may offer access to previously inaccessible length scales for characterizing tooth structures for dental research, opening exciting opportunities to address many central questions in dental research. New discoveries and fundamental breakthroughs in understanding are likely to follow. This review covers the applications, key findings, and future direction of SEM/FIB in dental research in morphology imaging, specimen preparation for transmission electron microscopy (TEM) analysis, and three-dimensional volume imaging using SEM/FIB tomography.

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Section: Introductionmentioning

confidence: 99%

Applications of scanning electron microscopy and focused ion beam milling in dental research

House

Long

O’Carroll

et al. 2022

European J Oral Sciences

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“…High-spatial-resolution x-ray computed tomography (CT) based on a full-field x-ray microscope, known as x-ray nanotomography (nano-computed tomography, nano-CT), is widely used for realizing nanometer-scale three-dimensional (3D) nondestructive observation of the inner structures of objects. Most variants, including those based on synchrotron-radiation (SR) sources and laboratory sources, are designed to be used at an x-ray energy range of less than 15 keV, [1][2][3][4][5][6][7][8][9][10][11][12][13] which is sufficient for many types of materials with sample dimensions less than several tens of micrometers [the typical field of view (FOV) for nano-CT systems]. However, for 3D imaging of high-Z materials, x rays must possess higher energy (several tens of keV).…”

Section: Introductionmentioning

confidence: 99%

High-energy x-ray nanotomography introducing an apodization Fresnel zone plate objective lens

Takeuchi

Uesugi

et al. 2021

Review of Scientific Instruments

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In this study, high-energy x-ray nanotomography (nano-computed tomography, nano-CT) based on full-field x-ray microscopy was developed. Fine two-dimensional and three-dimensional (3D) structures with linewidths of 75 nm-100 nm were successfully resolved in the x-ray energy range of 15 keV-37.7 keV. The effective field of view was ∼60 μm, and the typical measurement time for one tomographic scan was 30 min-60 min. The optical system was established at the 250-m-long beamline 20XU of SPring-8 to realize greater than 100× magnification images. An apodization Fresnel zone plate (A-FZP), specifically developed for high-energy x-ray imaging, was used as the objective lens. The design of the A-FZP for high-energy imaging is discussed, and its diffraction efficiency distribution is evaluated. The spatial resolutions of this system at energies of 15 keV, 20 keV, 30 keV, and 37.7 keV were examined using a test object, and the measured values are shown to be in good agreement with theoretical values. High-energy x-ray nano-CT in combination with x-ray micro-CT is applied for 3D multiscale imaging. The entire bodies of bulky samples, ∼1 mm in diameter, were measured with the micro-CT, and the nano-CT was used for nondestructive observation of regions of interest. Examples of multiscale CT measurements involving carbon steel, mouse bones, and a meteorite are discussed.

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“…Nano-resolution tomography and, in particular, nanoresolution spectro-tomography are regarded as a powerful modality of TXM with successful case studies spanning energy materials, environmental science, geoscience, etc. With the ongoing efforts in the developments of X-ray optics (Chang & Sakdinawat, 2014) and the next-generation X-ray facilities (Aljdaimi et al, 2018;Dong et al, 2019;Schneider, 1998;Zaman et al, 2019), further improvements in spatial, temporal resolution, and chemical sensitivity can be anticipated.…”

Section: Introductionmentioning

confidence: 99%

Deep-learning-based image registration for nano-resolution tomographic reconstruction

Zhang

Wang

et al. 2021

J Synchrotron Rad

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Nano-resolution full-field transmission X-ray microscopy has been successfully applied to a wide range of research fields thanks to its capability of non-destructively reconstructing the 3D structure with high resolution. Due to constraints in the practical implementations, the nano-tomography data is often associated with a random image jitter, resulting from imperfections in the hardware setup. Without a proper image registration process prior to the reconstruction, the quality of the result will be compromised. Here a deep-learning-based image jitter correction method is presented, which registers the projective images with high efficiency and accuracy, facilitating a high-quality tomographic reconstruction. This development is demonstrated and validated using synthetic and experimental datasets. The method is effective and readily applicable to a broad range of applications. Together with this paper, the source code is published and adoptions and improvements from our colleagues in this field are welcomed.

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Micron-scale crack propagation in laser-irradiated enamel and dentine studied with nano-CT

Cited by 14 publications

References 23 publications

Applications of scanning electron microscopy and focused ion beam milling in dental research

Applications of scanning electron microscopy and focused ion beam milling in dental research

High-energy x-ray nanotomography introducing an apodization Fresnel zone plate objective lens

Deep-learning-based image registration for nano-resolution tomographic reconstruction

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