Abstract
This study reports the effect of heat curing at 120 °C on the geopolymeric reaction and strength evolution in brown coal fly ash based geopolymer mortar and concrete. Moreover, an examination of this temperature profile of large size geopolymer concrete specimens is also reported. The specimen temperature and size were observed to influence the conversion from the glassy (amorphous) phases to the crystalline phases and the microstructure development of the geopolymer. The temperature profile could be divided into three principal stages which correlated well with the proposed reaction mechanism for class F fly ash geopolymers. The geopolymerisation progressed more rapidly for the mortar specimens than the concrete specimens with 12 to 14 h providing an optimum curing time for the 50 mm mortar cubes and 24 h being the optimum time for the 100 mm concrete cubes. The 50 mm and 100 mm concrete specimens’ compressive strengths in excess of 30 MPa could be obtained at 7 days. The structural integrity was not achieved at the center of 200 mm and 300 mm concrete specimens following 24 h curing at 120 °C. Hence, the optimal curing time required to achieve the best compressive strength for brown coal geopolymer was identified as being dependent on the specimen size.
Highlights
Conventional concrete produced by using Portland Cement (PC) as the main binder releases between 0.7 to 1.0 kg of CO2 per 1 kg of cement production [1,2], and as a result, is responsible for between 5 to 7% of anthropogenic CO2 emissions [1,2] which contributes to the global warming
This paper reports a study on the effect of elevated heat curing on the temperature profile and microstructure development in brown coal fly ash geopolymer mortar and concrete specimens
It is interesting to note that 50 mm geopolymer mortar and concrete cubes showed an almost identical temperature profile
Summary
Conventional concrete produced by using Portland Cement (PC) as the main binder releases between 0.7 to 1.0 kg of CO2 per 1 kg of cement production [1,2], and as a result, is responsible for between 5 to 7% of anthropogenic CO2 emissions [1,2] which contributes to the global warming. The Asia-Pacific population has grown to reach nearly 4.5 billion, while urbanization in most of the region is increasing. In response to this growth, the number of power plants across the region has increased significantly, bringing power to growing populations and industrial centers. The current emphasis is on developing novel low-CO2 binders, such as geopolymers, to meet the demand for concrete
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