Preferred orientation of calcium aluminosilicate hydrate induced by confined compression

The existing macroscale models of the calcium (alumino)silicate hydrate (C-(A-)S-H), the main binder of concrete, assume that the nanocrystallites maintain random orientation under any loading conditions. However, using synchrotron-radiation-based XRD, we report the development of preferred orientat...

Full description

Saved in:
Bibliographic Details
Published in:Cement and concrete research 2018-11, Vol.113, p.186-196
Main Authors: Geng, Guoqing, Vasin, Roman Nikolayevich, Li, Jiaqi, Qomi, Mohammad Javad Abdolhosseini, Yan, Jinyuan, Wenk, Hans-Rudolf, Monteiro, Paulo J.M.
Format: Article
Language:English
Subjects:
Aluminosilicates
Calcium
Calcium aluminosilicate hydrate
Calcium aluminum silicates
Calcium silicate hydrate
Cement
Deformation mechanisms
Deviatoric stress
Distribution functions
Elastic moduli
Fiber orientation
Gaussian distribution
High pressure X-ray diffraction
Nanocrystals
Nanostructured materials
Preferred orientation
Pressure
Texture
Texture formation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The existing macroscale models of the calcium (alumino)silicate hydrate (C-(A-)S-H), the main binder of concrete, assume that the nanocrystallites maintain random orientation under any loading conditions. However, using synchrotron-radiation-based XRD, we report the development of preferred orientation of nanocrystalline C-A-S-H, from random at ambient pressure to strongly oriented under uniaxial compression with lateral confinement. The c-axes of the nanocrystals tend to align with the primary load. This preferred orientation is preserved after removing of external loading. The texture, quantified using a standard Gaussian fiber orientation distribution function (ODF), was used to calculate the averaged bulk elastic tensor of oriented C-(A-)S-H. It changes from isotropic (without texture) to transversely isotropic (with texture). Our results provide direct evidence of the reorientation of nanocrystalline C-(A-)S-H as a mesoscale mechanism to the irreversible deformation of cement-based material. The implications of these results for modeling the mechanical property of C-(A-)S-H at the macroscale are discussed.
ISSN:0008-8846
1873-3948
DOI:10.1016/j.cemconres.2018.09.002