Radiation-induced Alteration of Meta-chert

Maruyama, Ippei; Kondo, Toshiaki; Sawada, Shohei; Halodová, Patricie; Fedoriková, Alica; Ohkubo, Takahiro; Murakami, Kenta; Igari, Takafumi; Rodriguez, Elena Tajuelo; Suzuki, Kenkichi

doi:10.3151/jact.20.760

Cited by 6 publications

(2 citation statements)

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“…As the physical properties of concrete depend on the properties of the aggregate, it is the behavior of the internal rock minerals that determines the properties of the aggregate. Aggregates in concrete have a decisive influence on the physical properties of concrete due to mineral strength, mineral bond strength, and mineral volume changes (Maruyama et al 2022;. In concrete structures around reactor buildings and pressure vessels, amorphization of minerals in aggregates due to neutron irradiation has occurred (Maruyama and Muto 2016;Silva et al 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Le Pape et al ( , 2020 proposed an empirical RIVE model by organizing and reanalyzing those data. In addition, recent experiments have confirmed that cracking associated with mineral expansion affects concrete deterioration (Maruyama et al 2022(Maruyama et al , 2023. Therefore, it will be important in the future to investigate not only mineral expansion but also aggregate expansion with respect to cracking in concrete deterioration.…”

Section: Introductionmentioning

confidence: 99%

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Study of Mechanical Properties of Silicate Minerals by Molecular Dynamics Simulation

Fujimura,

Hakozaki,

Sakuragi

et al. 2023

ACT

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The aging and damage of concrete buildings and structures is a problem in modern society. This is especially true for nuclear power plant buildings, which are required to have high safety standards. In this study, molecular dynamics simulations were performed to obtain mechanical properties for silicate minerals, including quartz, which is used as an aggregate in concrete. We also attempted to clarify phenomena including mechanical fracture. Mechanical properties of each mineral (Young's modulus, Poisson's ratio, and maximum stress) were obtained by performing tensile simulations on 10 silicate minerals which are -quartz, Orthoclase, Microcline, Albite, Oligoclase, Andesine, Labradorite, Augite, Diopside and Forsterite. Minerals other than -quartz were highly anisotropic with respect to Young's modulus. The maximum stress was highest for -quartz, but once a fracture started, the development of large fractures progressed at once and the stress relaxed rapidly. Deformation and fracture of the mineral in response to strain were analyzed by extracting the nonaffine component of the local displacement of atoms in tensile simulations. This analysis was able to explain the behavior of the stress-strain curve for each mineral. We also investigated how the composition of a mineral affects its mechanical fracture.

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Section: Introductionmentioning

confidence: 99%