Simulation on Mixed-Control of Dissolution and Boundary Nucleation and Growth Mechanisms of Tricalcium Silicate: Fid-Bau Portal

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Simulation on Mixed-Control of Dissolution and Boundary Nucleation and Growth Mechanisms of Tricalcium Silicate

Shen, Dejian / Wang, Xin

The C₃S hydration, like any other hydration reaction, involves the following unit processes: (1) reactions at the phase boundaries; (2) nucleation; (3) transport of mass through diffusion; and (4) crystal growth. These unit processes can occur simultaneously and interact with each other, making the whole hydration process rather complex and therefore bringing great challenges for understanding the hydration mechanisms of C₃S and cement. So far, the mechanisms controlling the induction period and main hydration peak in C₃S hydration have not been fully understood.

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Simulation on Mixed-Control of Dissolution and Boundary Nucleation and Growth Mechanisms of Tricalcium Silicate

Shen, Dejian / Wang, Xin

The C₃S hydration, like any other hydration reaction, involves the following unit processes: (1) reactions at the phase boundaries; (2) nucleation; (3) transport of mass through diffusion; and (4) crystal growth. These unit processes can occur simultaneously and interact with each other, making the whole hydration process rather complex and therefore bringing great challenges for understanding the hydration mechanisms of C₃S and cement. So far, the mechanisms controlling the induction period and main hydration peak in C₃S hydration have not been fully understood.

Simulation on Mixed-Control of Dissolution and Boundary Nucleation and Growth Mechanisms of Tricalcium Silicate

Shen, Dejian / Wang, Xin

The C₃S hydration, like any other hydration reaction, involves the following unit processes: (1) reactions at the phase boundaries; (2) nucleation; (3) transport of mass through diffusion; and (4) crystal growth. These unit processes can occur simultaneously and interact with each other, making the whole hydration process rather complex and therefore bringing great challenges for understanding the hydration mechanisms of C₃S and cement. So far, the mechanisms controlling the induction period and main hydration peak in C₃S hydration have not been fully understood.

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Title:

Simulation on Mixed-Control of Dissolution and Boundary Nucleation and Growth Mechanisms of Tricalcium Silicate

Contributors:

Shen, Dejian (author) / Wang, Xin (author)

Published in:

Simulation on Hydration of Tricalcium Silicate in Cement Clinker ; Chapter: 4 ; 65-108

Publication date:

2023-08-25

Size:

44 pages

ISBN:

978-981-99-4598-6 , 978-981-99-4597-9

DOI:

https://doi.org/10.1007/978-981-99-4598-6_4

Type of media:

Article/Chapter (Book)

Type of material:

Electronic Resource

Language:

English

Keywords:

Engineering , Civil Engineering , Geoengineering, Foundations, Hydraulics , Simulation and Modeling

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