Sage Journals: Discover world-class research

Abstract

Fly ash based geopolymer composite cubes were cast using class F fly ash, ground granulated blast furnace slag (GGBFS) as binders. The fluid-to-binder ratio was varied keeping all other parameters constant. The geopolymer composites were cured in different conditions. The composites were tested for compression at different ages. It is interesting to note that the variation of the strength with various fluid-to-binder ratios is unique irrespective of combination of materials, curing conditions, fluid content, and molarity of the fluid. The strength data generated was generalized to arrive at a phenomenological model. The model represents an unique pattern of strength development for the series of composite materials. The validity of the model was examined with an independent set of experimental data generated by the authors and Rangan. It was found that the predicted strengths were in line with the experimental strengths having a percentage error less than 6.0. The model is effective in re-proportioning of geopolymer composites in the field.

Keywords

geopolymer composites fly ash slag compressive strength fluid-to-binder ratio phenomenological model.

Get full access to this article

View all access options for this article.

References

Duxson, P. , Fernández-Jiménez, A. , Provis, J.L. , Lukey, G.C. , Palomo, A. and van Deventer , J.S.J. (2007). Geopolymer Technology: The Current State of the Art, Journal of Material Science, 42(9): 2917-2933.

Criado, M. , Fernández-Jiménez, A. and Palomo, A. (2007). Alkali Activation of Fly Ash: Effect of the SiO2/ Na2O Ratio Part I: FTIR Study, Microporous and Mesoporous Materials, 106: 180-191.

Xu, H. and van Deventer, J.S.J.V. ( 2000). The Geopolymerisation of Alumino-silicate Minerals, Int. J. Miner. Process, 59: 247-266.

Davidovits, J. (1994). Geopolymers: Inorganic Polymeric New Materials, J. Mater. Educ.,16:91-139.

Park, S.-S. and Kang, H.-Y. ( 2006). Strength and Microscopic Characteristics of Alkali Activated Fly ash Cement, Korean Journal of Chemical Engineering, 23(3): 367-373.

Yang, K.-H. , Song, J.-K. , Ashour, A.F. and Lee, E.-T. ( 2008). Properties of Cementless Mortars Activated by Sodium Silicate, Construction and Building Materials, 22: 1981-1989.

Davidovits, J. (1999). Chemistry of Geopolymeric Systems. Terminology, In: Proceedings of 99 Geopolymer Conference, 1: 9-40.

Lee, W.K.W. and van Deventer, J.S.J.V. (2007). Chemical Interactions between Siliceous Aggregates and Low-Ca Alkali-activated Cements, Cement and Concrete Research, 37: 844-855.

Zhao, F.-Q. , Ni, W. , Wang, H.-J. and Liu, H.-J. ( 2007). Activated Fly Ash/Slag Blended Cement Resources, Conservation and Recycling, 52: 303-313.

10.

Krivenko. P.V. (1992) Alkaline Cements, In: Proceeding, Ninth International Conference on the Chemistry of Cement, 4: 482-488.

11.

Taylor, H.F.W. (1993). Nanostructure of C-S-H: Current Status, Adv. Cement. Based. Mater., 1: 38-46.

12.

Duran Atis, C. , Bilim, C. , Çelik, O. and Karahan, O. (2009). Influence of Activator on the Strength and Drying Shrinkage of Alkali-activated Slag Mortar, Constr. Build. Mater., 23: 548-555.

13.

Puertas, F. , Martõnez-Ramõrez, S. , Alonso, S. and Vazquez, T. (2000). Alkali-activated Fly Ash/Slag Cement Strength behaviour and Hydration Products, Cement and Concrete Research, 30: 1625-1632.

14.

Rangan, B.V. ( 2008). Fly Ash-Based Geopolymer Concrete, Research Report GC4 Engineering Faculty Curtin University of Technology Perth , Australia.

15.

Rangan, B.V. ( 2008) Mix Design and Production of Fly Ash Based Geopolymer Concrete, The Indian Concrete journal, 82(5): 7-15.

16.

Nagaraj, T.S. and Banu, Z. (1996). Generalization of Abrams’ Law, Cement and Concrete Research, Elsevier Science, 26(6): 933-942.

17.

Radhakrishna, Shashishankar, A. and Nagaraj, T.S. (2006). Phenomenological Model for Assessment of Strength Development in Class F-Fly Ash Based Geopolymer Mortar, Indian Concrete Institute Journal , 7(1): 23-27.

18.

Radhakrishna, Shashishankar, A. and Udayashankar, B.C. (2008). Analysis and Assessment of Strength Development in Class F Fly Ash Based Compressed Geopolymer Blocks, The Indian Concrete Journal, 82(8): 31-37.

19.

Abrams, D. ( 1918). Design of Concrete Mixtures, Bulletin No. 1, Structural Materials Research Laboratory, Lewis Institute, Chicago, p. 20.

20.

Bolomey, J. ( 1927). Durecissenment Des Mortiers Ets Benton, Tech. Suisse. Romande, 16: 22-24.

Compressive Strength Assessment of Geopolymer Composites by a Phenomenological Model

Abstract

Keywords

Get full access to this article

References