Applications of <scp>X</scp>‐ray computed tomography for examining biophysical interactions and structural development in soil systems: a review

Helliwell, Jonathan; Sturrock, Craig J.; Grayling, K.M.; Tracy, Saoirse R.; Flavel, Richard J.; Young, Iain M.; Whalley, W. R.; Mooney, Sacha J.

doi:10.1111/ejss.12028

Cited by 180 publications

(107 citation statements)

References 138 publications

(319 reference statements)

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“…However, they all deal with plant-scale structural imaging of processes, i.e., they do not address the challenges associated with pore-scale imaging, multi-scale imaging, and correlative chemical mapping of the rhizosphere and associated modeling techniques. The use of X-ray computed tomography methods to probe root-soil macroscopic interactions has recently been reviewed by Helliwell et al (2013); Jones et al (2013); Mooney et al (2012). We will build on these reviews and focus on rhizosphere-specific aspects, i.e., high resolution imaging of root and soil architecture and interactions within the changing rhizosphere environment with specific relevance to mathematical modelling.…”

Section: Existing Work On Rhizosphere Imaging and Modelingmentioning

confidence: 99%

Challenges in imaging and predictive modeling of rhizosphere processes

et al. 2016

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Background Plant-soil interaction is central to human food production and ecosystem function. Thus, it is essential to not only understand, but also to develop predictive mathematical models which can be used to assess how climate and soil management practices will affect these interactions. Scope In this paper we review the current developments in structural and chemical imaging of rhizosphere processes within the context of multiscale mathematical image based modeling. We outline areas that need more research and areas which would benefit from more detailed understanding. Conclusions We conclude that the combination of structural and chemical imaging with modeling is an incredibly powerful tool which is fundamental for understanding how plant roots interact with soil. We emphasize the need for more researchers to be attracted to this area that is so fertile for future discoveries. Finally, model building must go hand in hand with experiments. In particular, there is a real need to integrate rhizosphere structural and chemical imaging with modeling for better understanding of the rhizosphere processes leading to models which explicitly account for pore scale processes.

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Section: Existing Work On Rhizosphere Imaging and Modelingmentioning

confidence: 99%

Challenges in imaging and predictive modeling of rhizosphere processes

et al. 2016

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“…X-ray computed tomography has been used for decades in science to reveal the internal structures of objects, from living beings to engineering materials (e.g., [31][32][33][34]) including the carbon materials used in the aluminum production industry [35][36][37][38][39]. Its main advantage is that it is a non-destructive technique.…”

Section: X-ray Computed Tomographymentioning

confidence: 99%

Application of Boron Oxide as a Protective Surface Treatment to Decrease the Air Reactivity of Carbon Anodes

Ishak

Picard

Laroche

et al. 2017

Metals

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Abstract:The oxidation of a carbon anode with air and CO 2 occurs during the electrolysis of alumina in Hall-Héroult cells, resulting in a significant overconsumption of carbon and dusting. Boron is well known to decrease the rate of this reaction for graphite. In this work, the application of boron oxide has been investigated to evaluate its inhibition effect on the air oxidation reaction, and to provide an effective protection for anodes. Different methods of impregnation coating have been explored. Impregnated anode samples were gasified under air at 525 • C according to the standard measurement methods. X-ray tomography was used to obtain the microstructural information of the samples before and after air-burning tests. The impregnated samples showed a very low oxidation reaction rate and dust generation.

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“…X-ray computed tomography has been used for decades now in science to reveal the internal structures of objects from living beings to engineering materials (e.g., [15][16][17][18]) including the carbon materials used in the aluminium production industry [19][20][21][22][23]. Its main advantage is that it is a non-destructive technique.…”

Section: X-ray Computed Tomographymentioning

confidence: 99%

Crack Detection Method Applied to 3D Computed Tomography Images of Baked Carbon Anodes

Picard

Lauzon-Gauthier

Duchesne

et al. 2016

Metals

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Carbon anodes used in the aluminium industry were imaged through destructive and non-destructive testing (NDT) methods. For the latter case, computed tomography (CT), which has previously been used to map the 3D apparent density distribution, was extended to crack detection. Previous work has shown how to overcome technical hurdles related to crack detection by using percolation-based algorithms operating on low-resolution images of full-scale baked carbon anodes. The previous application to 2D images was extended here to the 3D case. The crack detection algorithm has been performed on anode slices containing several independent macro cracks with different morphologies.

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Applications of X‐ray computed tomography for examining biophysical interactions and structural development in soil systems: a review

Cited by 180 publications

References 138 publications

Challenges in imaging and predictive modeling of rhizosphere processes

Challenges in imaging and predictive modeling of rhizosphere processes

Application of Boron Oxide as a Protective Surface Treatment to Decrease the Air Reactivity of Carbon Anodes

Crack Detection Method Applied to 3D Computed Tomography Images of Baked Carbon Anodes

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