A quantitative morphological analysis of nanostructured ceria–silica composite catalysts

This paper describes an image processing method for discriminating the inter-and intragranular delta phase precipitates in Inconel 718 (IN 718). The successive practical operations and the motivations of their choices are presented in detail. The method was applied to IN 718 specimens heat treated with different parameters to produce microstructures containing various amounts of both types of precipitates. They were characterized by electron microscopy in backscattered electron imaging. The main difficulty arose from the fact that the brightness distributions of inter-and intragranular precipitates partially overlap. Additional information on their morphology and their spatial distribution had to be exploited in order to differentiate them. The shape and the orientation of the precipitates were evaluated using the structure tensor, an operator that quantifies the directionality of the intensity distribution in an image. The distance between parallel precipitates was also used as an additional property to identify clusters of intragranular precipitates.

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“…An approach based on the covariance function, such as the one proposed in Moreaud et al . (), could provide such a tool.…”

Section: Discussionmentioning

confidence: 99%

Inter‐ and intragranular delta phase quantitative characterization in Inconel 718 by means of image analysis

Vanderesse

Anderson

Bridier

et al. 2016

Journal of Microscopy

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“…• refining with low environmental impact using more specialized catalysts, • improving post-treatment for making standard and hybrid motors cleaner and more efficient by means of a better understanding of soot nanostructure. Recently, many developments in visualization and analysis of catalysts using TEM micrographs have been proposed [1,2,3,4]. With TEM micrographs at high resolution, (see Figure 1) dark or bright linear patterns (fringes) can be observed and correspond to atomic plane of active phases deposited on the support.…”

Section: Introductionmentioning

confidence: 99%

“…The selectivity and activity can be linked to some descriptive parameters of the structure characterization [1] as, for instance, number of fringes per packet, interlayer spacing values and fringe lengths. We propose to use a model-based approach to characterize these fringes.…”

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confidence: 99%

ARFBF model for non stationary random fields and application in HRTEM images

Tan¹,

Atto²,

Alata

et al. 2015

2015 IEEE International Conference on Image Processing (ICIP)

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This paper presents a new model called Autoregressive Fractional Brownian Field (ARFBF) for analyzing textures which contain stationary and non-stationary components. The paper also proposes two estimation methods for the parameter of an isotropic fractional Brownian field based on Wavelet Packet (WP) spectrum: the Log-Regression on Diagonal WP spectrum (Log-RDWP) and the Log-Regression on Polar representation of WP spectrum (Log-RPWP). The Log-RPWP method provides a better estimation performance for small size images. We show the interest of ARFBF model and Log-RPWP for characterizing High-Resolution Transmission Electron Microscopy (HRTEM) images.

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“…7 illustrates a mixture of a crystalline and an amorphous material. The periodicity of the first one, and the lack of long-term regularity of the second one, drives the use of local Fourier attributes [26]. …”

Section: Introductory Examplesmentioning

confidence: 99%

Image processing for materials characterization: Issues, challenges and opportunities

Duval

Moreaud

Jeulin

et al. 2014

2014 IEEE International Conference on Image Processing (ICIP)

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This introductory paper aims at summarizing some problems and state-of-the-art techniques encountered in image processing for material analysis and design. Developing generic methods for this purpose is a complex task given the variability of the different image acquisition modalities (optical, scanning or transmission electron microscopy; surface analysis instrumentation, electron tomography, micro-tomography. . . ), and material composition (porous, fibrous, granular, hard materials, membranes, surfaces and interfaces. . . ). This paper presents an overview of techniques that have been and are currently developed to address this diversity of problems, such as segmentation, texture analysis, multiscale and directional features extraction, stochastic models and rendering, among others. Finally, it provides references to enter the issues, challenges and opportunities in materials characterization.

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A quantitative morphological analysis of nanostructured ceria–silica composite catalysts

Cited by 8 publications

References 7 publications

Inter‐ and intragranular delta phase quantitative characterization in Inconel 718 by means of image analysis

Inter‐ and intragranular delta phase quantitative characterization in Inconel 718 by means of image analysis

ARFBF model for non stationary random fields and application in HRTEM images

Image processing for materials characterization: Issues, challenges and opportunities

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