Micro- and Nano-Scales Three-Dimensional Characterisation of Softwood

Patera, Alessandra; Bonnin, Anne

doi:10.3390/jimaging7120263

Cited by 4 publications

(5 citation statements)

References 25 publications

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“…As follows from Table 4 , the strength of cellulose nanocrystals, assessed both by calculations and by experimental techniques, is 4.9–10 GPa, while the strength of nanofibrils with a diameter 3–15 nm is close to the lower end of this range [ 5 , 40 , 65 , 66 , 67 , 68 ]. These values exceed the strength of cellulose microfibers 8–12 µm in diameter, which is 0.5–1.65 GPa, by about one order of magnitude [ 5 , 40 , 66 , 104 , 106 , 107 ]. The typical nanohardness values H NI for cell walls with a thickness of 2–5 µm are about 0.3–0.5 GPa [ 70 , 71 , 72 , 73 , 74 , 75 , 107 , 108 , 109 , 110 ], which is 2–3 times less than the strength of cellulose microfibers.…”

Section: Size Effects In Woodmentioning

confidence: 98%

“…Nano- and micro-structures of cellulose materials and their properties strongly depend upon the specifics of interaction between nanocrystals in elementary fibrils and the ordering and binding of the latter in nano- and micro-fibers [ 103 , 104 , 105 , 106 , 107 ]. Mechanical, strength in particular, properties of cellulose nano- and micro-structures are structure sensitive, just as those of most other other organic and non-organic materials.…”

Section: Cellulose Microfibersmentioning

confidence: 99%

“…Results obtained using AFM and NI are in agreement with each other regarding the measurement accuracy, despite using different probes and measurement techniques, so that they are just as reliable as the ones obtained using the undebatable method of uniaxial tension. Usually, its tensile strength is two to three times higher than compression strength or hardness [ 5 , 40 , 104 , 106 , 107 ], unlike void-free materials, where the reversed value is quite typical. For example, the Tabor ratio for metals is well known, where hardness is three times higher than the yield stress.…”

Section: Cellulose Microfibersmentioning

confidence: 99%

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Multiscale Mechanical Performance of Wood: From Nano- to Macro-Scale across Structure Hierarchy and Size Effects

et al. 2022

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This review describes methods and results of studying the mechanical properties of wood at all scales: from nano- to macro-scale. The connection between the mechanical properties of material and its structure at all these levels is explored. It is shown that the existing size effects in the mechanical properties of wood, in a range of the characteristic sizes of the structure of about six orders of magnitude, correspond to the empirical Hall-Petch relation. This “law” was revealed more than 60 years ago in metals and alloys and later in other materials. The nature, as well as the particular type of the size dependences in different classes of materials can vary, but the general trend, “the smaller the stronger”, remains true both for wood and for other cellulose-containing materials. The possible mechanisms of the size effects in wood are being discussed. The correlations between the mechanical and thermophysical properties of wood are described. Several examples are used to demonstrate the possibility to forecast the macromechanical properties of wood by means of contactless thermographic express methods based on measuring temperature diffusivity. The research technique for dendrochronological and dendroclimatological studies by means of the analysis of microhardness and Young’s modulus radial dependences in annual growth rings is described.

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Section: Size Effects In Woodmentioning

confidence: 98%

Section: Cellulose Microfibersmentioning

confidence: 99%

Section: Cellulose Microfibersmentioning

confidence: 99%

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Multiscale Mechanical Performance of Wood: From Nano- to Macro-Scale across Structure Hierarchy and Size Effects

et al. 2022

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“…This makes it an attractive technique whenever the integrity of the sample is crucial, as e.g. in bio-medical imaging [11,23,28,35,45], archaeometry [38,40], paleontology [13], industrial quality control [7,33], and material science [14,42].…”

Section: Introductionmentioning

confidence: 99%

A versatile laboratory setup for high resolution X-ray phase contrast tomography and scintillator characterization

Dierks

Stjärneblad

Wallentin

2023

XST

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BACKGROUND: X-ray micro-tomography (μCT) is a powerful non-destructive 3D imaging method applied in many scientific fields. In combination with propagation-based phase-contrast, the method is suitable for samples with low absorption contrast. Phase contrast tomography has become available in the lab with the ongoing development of micro-focused tube sources, but it requires sensitive and high-resolution X-ray detectors. The development of novel scintillation detectors, particularly for microscopy, requires more flexibility than available in commercial tomography systems. OBJECTIVE: We aim to develop a compact, flexible, and versatile μCT laboratory setup that combines absorption and phase contrast imaging as well as the option to use it for scintillator characterization. Here, we present details on the design and implementation of the setup. METHODS: We used the setup for μCT in absorption and propagation-based phase contrast mode, as well as to study a perovskite scintillator. RESULTS: We show the 2D and 3D performance in absorption and phase contrast mode, as well as how the setup can be used for testing new scintillator materials in a realistic imaging environment. A spatial resolution of around 1.3μm is measured in 2D and 3D. CONCLUSIONS: The setup meets the needs for common absorption μCT applications and offers the increased contrast in the phase contrast mode. The availability of a versatile laboratory μCT setup allows not only for easy access to tomographic measurements, but also enables a prompt monitoring and feedback beneficiary for advances in scintillator fabrication.

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“…Further topics covered in this Special Issue include the use of synchrotron light for phase-contrast and multi-contrast imaging [ 8 , 9 , 10 , 11 ] and analytical techniques, such as microscopic synchrotron X-ray fluorescence [ 12 ]. Several contributions deal with new performing algorithms developed for the suppression of cone-beam artifacts in CT images [ 13 ] and signal retrieval from non-sinusoidal intensity modulations in X-ray and neutron interferometry [ 14 ], or devoted to innovative techniques, such as multiscale holotomography [ 15 ], rotation-free dynamic multi-angle X-ray tomography [ 16 ] and high-speed X-ray imaging [ 17 ].…”

mentioning

confidence: 99%