Study on mechanical strength and early hydration properties of cement paste modified by polycarboxylate superplasticizer with slump retention

1 FTIR spectra of PCE-SR All authors
2 Fluidity of cement paste with PCE-SR
3 Adsorption amount of PCE-SR on cement particle
4 Mechanical strength of specimens with different contents of PCE-SR: (a) 7 d, and (b) 28 d
5 Micro-calorimetric curves of cement paste with different contents of PCE-SR: (a) Hydration heat flow and (b) Cumulative heat flow
6 XRD patterns of specimens with different contents of PCE-SR: (a) 3 d and (b) 7 d
7 SEM micrograph of hydration products of cement (×10.0k): (a) control sample, (b) 0.2% PCE-SR, (c) 0.4% PCE-SR, (d) 0.6% PCE-SR, (e) 0.8% PCE-SR, (f) 1.0% PCE-SR

The polycarboxylate superplasticizer with slump retention capabilities (PCE-SR) may significantly enhance concrete cohesiveness and construction performance because of its high water reduction rate and outstanding slump retention. In order to explore the effective mechanism of PCE-SR on cement paste, this paper investigates the influence of PCE-SR on the mechanical strength and microstructure of hardened cement. The results indicate that PCE-SR might effectively reduce cement water usage and the water reduction rate by as much as 30%. With the addition of PCE-SR, the mechanical strength of hardened cement paste was improved and the hydration process and hydration heat were reduced. In addition, the microstructure of hardened cement paste might be enhanced with PCE-SR added due to reduced porosity of the hardened specimens.

1 Introduction

Concrete and cement-based materials are the primary foundations for the capital construction of a country due to their widely used and large consumption [1]. High-performance concrete, which has superior workability, mechanical strength, and durability, is the inevitable direction of technology development as science and technology advance [2-3].

In order to improve the workability and the mechanical strength of cement-based materials, concrete additives, especially superplasticizers, have become an indispensable part of concrete engineering [4-5]. Currently, the polycarboxylate...

TEXT Lin Haiyan1, Guo Yanfei1, Zhi Zhenzhen1, Jiao Yaxin1, Wang Liting1, Wang Yujiang1, Ji Yaqiong2, Sayed Ali Khan3,4
1School of Materials Science and Engineering, Luoyang Institute of Science and Technology, Luoyang/China
2China United Cement of Luoyang Co., Ltd, Luoyang/China
3Hoffman Institute of Advanced Materials, Shenzhen Polytechnic, Liuxian Blvd, Nanshan District, Shenzhen/China
4Department of Chemistry and Chemical Biology, Rutgers University, Piscataway, New Jersey/USA

This article appeared in

ZKG 7/2023

This article appeared in

ZKG 7/2023

Ressort:  Materials
subscription Content

Related articles:

Issue 8/2022 WUHAN UNIVERSITY OF SCIENCE AND TECHNOLOGY | WUHAN TEXTILE UNIVERSITY | CHINA CONSTRUCTION THIRD BUREAU FIRST ENGINEERING CO., LTD.

Physical-mechanical properties and hydration microstructure of slag powder/cement system with different nanoparticles

Nano-silica (NS) and self-made nano-calcium silicate hydrate (NC) were mixed into the slag powder/cement system, and the effects of the two on the physical-mechanical properties and hydration...

more
Issue 7-8/2016 WUHAN UNIVERSITY OF TECHNOLOGY, WUHAN/CHINA

Effect of the ester group in side chain of ­polycarboxylate superplasticizer on ­the ­cement hydration process

In this paper, the effect of the presence of the ester group in side chain of polycarboxylate superplasticizer (PC) on the cement hydration process...

more
Issue 01/2012

Hydration of ternary blended cement in the presence of PC type superplasticizer

During the last few decades, the construction industry has increased the use of both mineral admixtures such as fly ash and chemical admixtures such...

more
Issue 02/2024 WUHAN TEXTILE UNIVERSITY

Effect of calcium formate/nano C-S-H composite on early hydration and microstructure of the GGBS-cement system under steam curing

The influence of calcium formate (CF)/nano C-S-H (NC) composite on the early strength of the ground granulated blast-furnace slag (GGBS)-cement system under steam curing conditions was investigated, and the mechanism behind was analyzed by means of XRD, FTIR and MIP.

more