MOSAIC: An Effective FFT-based Numerical Method to Assess Aging Properties of Concrete

Torrence, Christa E.; Giorl, Alain B.; Li, Yujie; Rodriguez, Elena Tajuelo; Mena, J.D. Arregui; Rosseel, Thomas M.; Pape, Yann Le

doi:10.3151/jact.19.149

Cited by 18 publications

(4 citation statements)

References 68 publications

(70 reference statements)

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“…"MOSAIC utilizes compositional phase maps to simulate damage from radiation-induced volumetric expansion, applied force, creep, and thermal expansion. This compositional detail allows each mineral in the microstructure to be assigned specific material properties, allowing the simulation to be as accurate and representative as possible.The principal goal of MOSAIC is to simulate the effects of nonlinear aging mechanisms occurring in nuclear concrete on the macroscopic mechanical properties, using only the aggregate microstructure compositional information as a starting point" [5].…”

Section: Mosaic Capabilities 21 What Is Mosaic?mentioning

confidence: 99%

Methodological guidelines on concrete degradation based on predictive models and the release of MOSAIC for industry use

Le Pape

2024

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Section: Mosaic Capabilities 21 What Is Mosaic?mentioning

confidence: 99%

Methodological guidelines on concrete degradation based on predictive models and the release of MOSAIC for industry use

Le Pape

2024

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“…Using fast-Fourier transform (FFT)-based simulation methods [20,21,11], MOSAIC makes it possible to run efficient mechanical simulations of complex microstructures and to derive their effective mechanical behavior assuming periodic boundary conditions. The capabilities of MOSAIC are fully described in the paper by Torrence et al [26]. The current maximum pixel size of a 2D microstructure is limited to 1,024 × 1,024.…”

Section: Mosaicmentioning

confidence: 99%

Microstructural Simulation of Ion-Irradiated Natural Rocks and Minerals

Pape¹,

Alnaggar²

2023

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This report details the contribution of Oak Ridge National Laboratory to the Nuclear Energy University Program (NEUP) project, "Rapid Characterization of Concrete Mineralogy using Multi-Scale Tools" led by the University of Illinois at Urbana-Champaign. To support the subsequent license renewal (SLR) of the US nuclear power plants (NPPs) fleet, the performance of concrete-forming aggregates against neutron irradiation needs to be assessed. Ion irradiation is proposed as a rapid, cost-effective surrogate method to full neutron irradiation testing. To complement the characterization of ion-irradiated rock specimens, ORNL has run finite-elements and fast-Fourier transform (FFT-based) simulations using the codes MARS and Microstructure-Oriented Scientific Analysis of Irradiated Concrete (MOSAIC). The main conclusion of this analysis is that the apparent post-ion-irradiation step-height underestimates the accumulated free radiation-induced volumetric expansion (RIVE) in the ion-implanted depth by about 15% at full amorphization and about 25% toward the beginning of the ion irradiation experiment. The discrepancy is explained by the fact that the step height is proportional to the sum of the RIVE (i.e., one third of the RIVE) and the irradiation-assisted plastic strains in the vertical direction (lower than two thirds of the RIVE). Because of the large lateral compressive stresses caused by the restraining effect of the unirradiated substrate, the stress field in the mineral grains and at the grain boundary (GB) in the ion-implanted layer is much different than the comparable stress field occurring during neutron irradiation. Hence, the mismatch RIVE causing cracks in the rock-forming minerals leads to different cracking patterns. Ion irradiation continues to be used as a rapid technique to assess the RIVE potential of rocks.

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“…2) Investigation of aggregate expansion considering the inhomogeneous volume expansion of rock-forming minerals (Elleuch et al 1972;Hilsdorf et al 1978;Denisov et al 2012;Maruyama et al 2017b;Štemberk 2021a, 2021b). 3) Deriving concrete degradation as a function of aggregate expansion (Dubrovskii et al 1966a(Dubrovskii et al 1966b(Dubrovskii et al , 1968(Dubrovskii et al , 1970Elleuch et al 1972;Hilsdorf et al 1978;Denisov et al 2012;Giorla et al 2015;Le Pape et al 2015, 2016Pomaro 2016;Maruyama et al 2017b;Li et al 2020;Sasano et al 2020;Saklani et al 2021;Torrence et al 2021;Pomaro et al 2022). 4) Performance evaluation of reinforced concrete members considering neutron attenuation and resultant distribution of degradation under complex restraint conditions (Bruck et al 2019;Kambayashi et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Radiation-induced Alteration of Meta-chert

Maruyama

Kondo

Sawada

et al. 2022

ACT

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Concrete aggregate identified as "meta-chert" was irradiated with gamma-rays and neutrons. To identify the volume expansion of the aggregate under neutron irradiation, the following analyses were performed for pristine and irradiated α-quartz and metachert: X-ray diffraction (XRD)/Rietveld analysis, dimension change, water pycnometry, He-pycnometry, light optical microscopy (LOM), and scanning electron microscopy (SEM). From the difference of volume expansion observed from dimension change and water/helium pycnometry, the crack opening inside the aggregate subjected to irradiation was elucidated, and this was confirmed by LOM and SEM analysis. The crack contribution to the expansion of the aggregate was significant for neutron fluence > 6.99 × 10 19 n/cm 2 , for E ≥ 0.01 MeV. Based on the XRD analysis, changes in lattice parameters were identified and the cell volume expansion was compared with the data obtained by helium pycnometry. Based on the density change calculation and phase calculation data, the density of X-ray amorphous phase was consistent with that of expanded crystal α-quartz.

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MOSAIC: An Effective FFT-based Numerical Method to Assess Aging Properties of Concrete

Cited by 18 publications

References 68 publications

Methodological guidelines on concrete degradation based on predictive models and the release of MOSAIC for industry use

Methodological guidelines on concrete degradation based on predictive models and the release of MOSAIC for industry use

Microstructural Simulation of Ion-Irradiated Natural Rocks and Minerals

Radiation-induced Alteration of Meta-chert

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