Unknown

Dataset Information

0

Densification of the interlayer spacing governs the nanomechanical properties of calcium-silicate-hydrate.


ABSTRACT: Calciuam-silicate-hydrate (C-S-H) is the principal binding phase in modern concrete. Molecular simulations imply that its nanoscale stiffness is 'defect-driven', i.e., dominated by crystallographic defects such as bridging site vacancies in its silicate chains. However, experimental validation of this result is difficult due to the hierarchically porous nature of C-S-H down to nanometers. Here, we integrate high pressure X-ray diffraction and atomistic simulations to correlate the anisotropic deformation of nanocrystalline C-S-H to its atomic-scale structure, which is changed by varying the Ca-to-Si molar ratio. Contrary to the 'defect-driven' hypothesis, we clearly observe stiffening of C-S-H with increasing Ca/Si in the range 0.8???Ca/Si???1.3, despite increasing numbers of vacancies in its silicate chains. The deformation of these chains along the b-axis occurs mainly through tilting of the Si-O-Si dihedral angle rather than shortening of the Si-O bond, and consequently there is no correlation between the incompressibilities of the a- and b-axes and the Ca/Si. On the contrary, the intrinsic stiffness of C-S-H solid is inversely correlated with the thickness of its interlayer space. This work provides direct experimental evidence to conduct more realistic modelling of C-S-H-based cementitious material.

SUBMITTER: Geng G 

PROVIDER: S-EPMC5591233 | biostudies-literature | 2017 Sep

REPOSITORIES: biostudies-literature

altmetric image

Publications

Densification of the interlayer spacing governs the nanomechanical properties of calcium-silicate-hydrate.

Geng Guoqing G   Myers Rupert J RJ   Qomi Mohammad Javad Abdolhosseini MJA   Monteiro Paulo J M PJM  

Scientific reports 20170908 1


Calciuam-silicate-hydrate (C-S-H) is the principal binding phase in modern concrete. Molecular simulations imply that its nanoscale stiffness is 'defect-driven', i.e., dominated by crystallographic defects such as bridging site vacancies in its silicate chains. However, experimental validation of this result is difficult due to the hierarchically porous nature of C-S-H down to nanometers. Here, we integrate high pressure X-ray diffraction and atomistic simulations to correlate the anisotropic de  ...[more]

Similar Datasets

| S-EPMC10518866 | biostudies-literature
| S-EPMC6304137 | biostudies-literature
| S-EPMC5109495 | biostudies-literature
| S-EPMC10536101 | biostudies-literature
| S-EPMC5710188 | biostudies-other
| S-EPMC8712522 | biostudies-literature
| S-EPMC11336121 | biostudies-literature
| S-EPMC9229557 | biostudies-literature
| S-EPMC7721899 | biostudies-literature
| S-EPMC5553423 | biostudies-literature