A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
Abstract Cracking can significantly accelerate mass transport in concrete and as such, impact its durability. This paper is aimed at quantifying the effect of saturated cracks on ion diffusion. Electrical conductivity, measured by electrical impedance spectroscopy (EIS), was used to characterize the diffusion coefficient of fiber-reinforced cement paste disks that contained one or two through-thickness cracks. Crack widths in the range 20–100 μm were generated by controlled indirect tension test. Crack profiles were digitized and quantified by image analysis to determine crack volume fraction and average crack width. Crack connectivity (e.g., inverse of tortuosity) was calculated from the conductivity results measured by EIS. The results suggest that the diffusion coefficient of cracked samples is strongly and linearly related to the crack volume fraction; but is not directly dependent on crack width. Crack tortuosity does reduce the ion diffusion through cracks, but its impact is not very significant. Overall, the most important parameter governing ion diffusion in saturated cracked concrete is the volume fraction of cracks. Theoretical justifications of these observations are also provided.
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
Abstract Cracking can significantly accelerate mass transport in concrete and as such, impact its durability. This paper is aimed at quantifying the effect of saturated cracks on ion diffusion. Electrical conductivity, measured by electrical impedance spectroscopy (EIS), was used to characterize the diffusion coefficient of fiber-reinforced cement paste disks that contained one or two through-thickness cracks. Crack widths in the range 20–100 μm were generated by controlled indirect tension test. Crack profiles were digitized and quantified by image analysis to determine crack volume fraction and average crack width. Crack connectivity (e.g., inverse of tortuosity) was calculated from the conductivity results measured by EIS. The results suggest that the diffusion coefficient of cracked samples is strongly and linearly related to the crack volume fraction; but is not directly dependent on crack width. Crack tortuosity does reduce the ion diffusion through cracks, but its impact is not very significant. Overall, the most important parameter governing ion diffusion in saturated cracked concrete is the volume fraction of cracks. Theoretical justifications of these observations are also provided.
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
Akhavan, Alireza (author) / Rajabipour, Farshad (author)
2012
Article (Journal)
English
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
| Springer Verlag | 2012
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
| Online Contents | 2012
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
| Online Contents | 2013
Evaluating ion diffusivity of cracked cement paste using electrical impedance spectroscopy
| British Library Online Contents | 2013
Electrical properties of cement paste obtained from impedance spectroscopy
| British Library Online Contents | 1995