Compressive Strength and Workability Characteristics of Low-Calcium Fly ash-based Self-Compacting Geopolymer Concrete
Due to growing environmental concerns of the cement
industry, alternative cement technologies have become an area of
increasing interest. It is now believed that new binders are
indispensable for enhanced environmental and durability
performance. Self-compacting Geopolymer concrete is an innovative
method and improved way of concreting operation that does not
require vibration for placing it and is produced by complete
elimination of ordinary Portland cement.
This paper documents the assessment of the compressive strength
and workability characteristics of low-calcium fly ash based selfcompacting
geopolymer concrete. The essential workability
properties of the freshly prepared Self-compacting Geopolymer
concrete such as filling ability, passing ability and segregation
resistance were evaluated by using Slump flow, V-funnel, L-box and
J-ring test methods. The fundamental requirements of high
flowability and segregation resistance as specified by guidelines on
Self Compacting Concrete by EFNARC were satisfied. In addition,
compressive strength was determined and the test results are included
here. This paper also reports the effect of extra water, curing time and
curing temperature on the compressive strength of self-compacting
geopolymer concrete. The test results show that extra water in the
concrete mix plays a significant role. Also, longer curing time and
curing the concrete specimens at higher temperatures will result in
higher compressive strength.
[1] V.M. Malhotra, "Introduction: Sustainable Development & Concrete
Technology", ACI Concrete International, 24(7), pp. 22, 2002.
[2] R. McCaffrey, "Climate Change and the Cement Industry", Global
Cement and Lime Magazine, (Environmental Special Issue), pp. 15-19,
2002.
[3] D. Hardjito, S. E. Wallah, D. M. J. Sumajouw, and B. V. Rangan,
"Factors Influencing the Compressive Strength of Fly ash-Based
Geopolymer Concrete", Civil Engineering Dimension, Vol. 6, No. 2,
pp. 88-93, September 2004.
[4] T. R. Naik, "Sustainability of cement and concrete industries",
Proceedings of the International Conference Global Construction:
Ultimate Concrete Opportunities, Dundee, Scotland, pp. 141-150, July
2005.
[5] Tarek Salloum, "Effect of Fly ash Replacement on Alkali and Sulphate
Resistance of Mortars", MS Thesis, Department of Building, Civil and
Environmental Engineering, Concordia University Montreal, Quebec,
Canada, July 2007.
[6] J. Davidovits, "Geopolymers: inorganic polymeric new materials",
Journal of Thermal Analysis, 37(8), pp. 1633-1656, 1991.
[7] J. Temuujin, A. van Riessen, K. J. D. MacKenzie, "Preparation and
characterisation of fly ash based geopolymer mortars", Construction
and Building Materials, 24 (2010), pp. 1906-1910.
[8] J. Davidovits, "Geopolymer chemistry & sustainable development",
The Poly(sialate) terminology: a very useful and simple model for the
promotion and understanding of green-chemistry, in: J. Davidovits
(Ed.), Proceedings of the World Congress Geopolymer, Saint Quentin,
France, 28 June-1 July, 2005, pp. 9-15.
[9] J. Davidovits, D. C. Comrie, J. H. Paterson, and D. J. Ritcey,
"Geopolymeric Concretes for Environmental Protection", Concrete
International: Design & Construction, Vol.12, No.7, pp. 30-40, July
1990.
[10] Pavel Rovnanik, "Effect of curing temperature on the development of
hard structure of metakaolin-based geopolymer", Construction and
Building Materials, 24 (2010), pp. 1176-1183.
[11] Franck Cassagnabère, Michel Mouret, Gilles Escadeillas, Philippe
Broilliard, Alexandre Bertrand, "Metakaolin, a solution for the precast
industry to limit the clinker content in concrete: Mechanical aspects",
Construction and Building Materials, 24 (2010), pp. 1109-1118.
[12] Ubolluk Rattanasak, Prinya Chindaprasirt, "Influence of NaOH solution
on the synthesis of fly ash geopolymer", Minerals Engineering, 22
(2009), pp. 1073-1078.
[13] A. Palomo, M. W. Grutzeck, M. T. Blanco, "Alkali-activated fly ashes:
A cement for the future", Cement and Concrete Research, 29 (8), pp.
1323-1329, 1999.
[14] D. Hardjito, and B. V. Rangan, "Development and Properties of Low-
Calcium Fly ash based Geopolymer Concrete", Research report GC-1,
Faculty of Engineering, Curtin University of Technology, Perth,
Australia, 2005.
[15] B. V. Rangan, "Fly Ash-Based Geopolymer Concrete", Research
Report GC-4, Faculty of Engineering, Curtin University of Technology,
Perth, Australia, 2008.
[16] Jae Eun Oh, Paulo J.M. Monteiro, Ssang Sun Jun, Sejin Choi, Simon
M. Clark, "The evolution of strength and crystalline phases for alkaliactivated
ground blast furnace slag and fly ash-based geopolymers",
Cement and Concrete Research, 40 (2010), pp. 189-196.
[17] M. Resheidat, S. A. Alzyoud, "SCC Development in Jordan", ICCBT
2008 - A - (29), pp. 319 - 332, 2008
[18] Hariyadi, M. W. Tjaronge, R .Djamaluddin and A. M. Akkas,
"Experimental Study of Slump Flow and Compressive Strength of Selfcompacting
Concrete Containing Tailing and Portland Composite
Cement", Proceedings of the First Makassar International Conference
on Civil Engineering (MICCE2010), March 9-10, 2010.
[19] S. Hemant, R. K. Khitoliya, S. S. Pathak, "Incorporating European
Standards for Testing Self Compacting Concrete in Indian Conditions",
International Journal of Recent Trends in Engineering, Vol. 1, No. 6,
May 2009.
[20] Hajime Okamura, "Self Compacting High Performance Concrete",
Concrete International, pp. 50-54, 1997.
[21] M. Ouchi, "Self-Compacting Concrete: Development, Applications,
and Investigations", Nordic Concrete Research, Publication 23, 1999.
[22] EFNARC, "Specification and Guidelines for Self-Compacting
Concrete", February 2002.
[23] Cristian Druta, "Tensile Strength and Bonding Characteristics of Self-
Compacting Concrete", MS Thesis, Department of Engineering Science,
Polytechnic University of Bucharest, August 2003.
[24] F. Nuruddin, A. Kusbiantoro, S. Qazi, N. Shafiq, "The Effect of Natural
Retarder On Fly Ash Based Geopolymer Concrete", Proceedings of
International Conference on Sustainable Building and Infrastructure
(ICSBI 2010), 15-17 June 2010, Kuala Lumpur Convention Centre.
[25] V. F. F. Barbosa, K. J. D. MacKenzie, C. Thaumaturgo, "Synthesis and
characterisation of materials based on inorganic polymers of alumina
and silica: Sodium polysialate polymers", International Journal of
Inorganic Materials, 2 (4), pp. 309-317, 2000.
[26] Djwantoro Hardjito, Chua Chung Cheak & Carrie Ho Lee Ing,
"Strength and Setting Times of Low Calcium Fly Ash-based
Geopolymer Mortar", Modern Applied Science, 2 (4), pp. 3-11, 2008.
[27] J. G. S. van Jaarsveld, J. S. J. van Devener, and G. C. Lukey, "The
effect of composition and Temperature on the Properties of Fly ash and
Kaolinite-based Geopolymers", Chemical Engineering Journal, 89 (1-
3), pp. 63-73, 2002.
[1] V.M. Malhotra, "Introduction: Sustainable Development & Concrete
Technology", ACI Concrete International, 24(7), pp. 22, 2002.
[2] R. McCaffrey, "Climate Change and the Cement Industry", Global
Cement and Lime Magazine, (Environmental Special Issue), pp. 15-19,
2002.
[3] D. Hardjito, S. E. Wallah, D. M. J. Sumajouw, and B. V. Rangan,
"Factors Influencing the Compressive Strength of Fly ash-Based
Geopolymer Concrete", Civil Engineering Dimension, Vol. 6, No. 2,
pp. 88-93, September 2004.
[4] T. R. Naik, "Sustainability of cement and concrete industries",
Proceedings of the International Conference Global Construction:
Ultimate Concrete Opportunities, Dundee, Scotland, pp. 141-150, July
2005.
[5] Tarek Salloum, "Effect of Fly ash Replacement on Alkali and Sulphate
Resistance of Mortars", MS Thesis, Department of Building, Civil and
Environmental Engineering, Concordia University Montreal, Quebec,
Canada, July 2007.
[6] J. Davidovits, "Geopolymers: inorganic polymeric new materials",
Journal of Thermal Analysis, 37(8), pp. 1633-1656, 1991.
[7] J. Temuujin, A. van Riessen, K. J. D. MacKenzie, "Preparation and
characterisation of fly ash based geopolymer mortars", Construction
and Building Materials, 24 (2010), pp. 1906-1910.
[8] J. Davidovits, "Geopolymer chemistry & sustainable development",
The Poly(sialate) terminology: a very useful and simple model for the
promotion and understanding of green-chemistry, in: J. Davidovits
(Ed.), Proceedings of the World Congress Geopolymer, Saint Quentin,
France, 28 June-1 July, 2005, pp. 9-15.
[9] J. Davidovits, D. C. Comrie, J. H. Paterson, and D. J. Ritcey,
"Geopolymeric Concretes for Environmental Protection", Concrete
International: Design & Construction, Vol.12, No.7, pp. 30-40, July
1990.
[10] Pavel Rovnanik, "Effect of curing temperature on the development of
hard structure of metakaolin-based geopolymer", Construction and
Building Materials, 24 (2010), pp. 1176-1183.
[11] Franck Cassagnabère, Michel Mouret, Gilles Escadeillas, Philippe
Broilliard, Alexandre Bertrand, "Metakaolin, a solution for the precast
industry to limit the clinker content in concrete: Mechanical aspects",
Construction and Building Materials, 24 (2010), pp. 1109-1118.
[12] Ubolluk Rattanasak, Prinya Chindaprasirt, "Influence of NaOH solution
on the synthesis of fly ash geopolymer", Minerals Engineering, 22
(2009), pp. 1073-1078.
[13] A. Palomo, M. W. Grutzeck, M. T. Blanco, "Alkali-activated fly ashes:
A cement for the future", Cement and Concrete Research, 29 (8), pp.
1323-1329, 1999.
[14] D. Hardjito, and B. V. Rangan, "Development and Properties of Low-
Calcium Fly ash based Geopolymer Concrete", Research report GC-1,
Faculty of Engineering, Curtin University of Technology, Perth,
Australia, 2005.
[15] B. V. Rangan, "Fly Ash-Based Geopolymer Concrete", Research
Report GC-4, Faculty of Engineering, Curtin University of Technology,
Perth, Australia, 2008.
[16] Jae Eun Oh, Paulo J.M. Monteiro, Ssang Sun Jun, Sejin Choi, Simon
M. Clark, "The evolution of strength and crystalline phases for alkaliactivated
ground blast furnace slag and fly ash-based geopolymers",
Cement and Concrete Research, 40 (2010), pp. 189-196.
[17] M. Resheidat, S. A. Alzyoud, "SCC Development in Jordan", ICCBT
2008 - A - (29), pp. 319 - 332, 2008
[18] Hariyadi, M. W. Tjaronge, R .Djamaluddin and A. M. Akkas,
"Experimental Study of Slump Flow and Compressive Strength of Selfcompacting
Concrete Containing Tailing and Portland Composite
Cement", Proceedings of the First Makassar International Conference
on Civil Engineering (MICCE2010), March 9-10, 2010.
[19] S. Hemant, R. K. Khitoliya, S. S. Pathak, "Incorporating European
Standards for Testing Self Compacting Concrete in Indian Conditions",
International Journal of Recent Trends in Engineering, Vol. 1, No. 6,
May 2009.
[20] Hajime Okamura, "Self Compacting High Performance Concrete",
Concrete International, pp. 50-54, 1997.
[21] M. Ouchi, "Self-Compacting Concrete: Development, Applications,
and Investigations", Nordic Concrete Research, Publication 23, 1999.
[22] EFNARC, "Specification and Guidelines for Self-Compacting
Concrete", February 2002.
[23] Cristian Druta, "Tensile Strength and Bonding Characteristics of Self-
Compacting Concrete", MS Thesis, Department of Engineering Science,
Polytechnic University of Bucharest, August 2003.
[24] F. Nuruddin, A. Kusbiantoro, S. Qazi, N. Shafiq, "The Effect of Natural
Retarder On Fly Ash Based Geopolymer Concrete", Proceedings of
International Conference on Sustainable Building and Infrastructure
(ICSBI 2010), 15-17 June 2010, Kuala Lumpur Convention Centre.
[25] V. F. F. Barbosa, K. J. D. MacKenzie, C. Thaumaturgo, "Synthesis and
characterisation of materials based on inorganic polymers of alumina
and silica: Sodium polysialate polymers", International Journal of
Inorganic Materials, 2 (4), pp. 309-317, 2000.
[26] Djwantoro Hardjito, Chua Chung Cheak & Carrie Ho Lee Ing,
"Strength and Setting Times of Low Calcium Fly Ash-based
Geopolymer Mortar", Modern Applied Science, 2 (4), pp. 3-11, 2008.
[27] J. G. S. van Jaarsveld, J. S. J. van Devener, and G. C. Lukey, "The
effect of composition and Temperature on the Properties of Fly ash and
Kaolinite-based Geopolymers", Chemical Engineering Journal, 89 (1-
3), pp. 63-73, 2002.
@article{"International Journal of Architectural, Civil and Construction Sciences:52638", author = "M. Fareed Ahmed and M. Fadhil Nuruddin and Nasir Shafiq", title = "Compressive Strength and Workability Characteristics of Low-Calcium Fly ash-based Self-Compacting Geopolymer Concrete", abstract = "Due to growing environmental concerns of the cement
industry, alternative cement technologies have become an area of
increasing interest. It is now believed that new binders are
indispensable for enhanced environmental and durability
performance. Self-compacting Geopolymer concrete is an innovative
method and improved way of concreting operation that does not
require vibration for placing it and is produced by complete
elimination of ordinary Portland cement.
This paper documents the assessment of the compressive strength
and workability characteristics of low-calcium fly ash based selfcompacting
geopolymer concrete. The essential workability
properties of the freshly prepared Self-compacting Geopolymer
concrete such as filling ability, passing ability and segregation
resistance were evaluated by using Slump flow, V-funnel, L-box and
J-ring test methods. The fundamental requirements of high
flowability and segregation resistance as specified by guidelines on
Self Compacting Concrete by EFNARC were satisfied. In addition,
compressive strength was determined and the test results are included
here. This paper also reports the effect of extra water, curing time and
curing temperature on the compressive strength of self-compacting
geopolymer concrete. The test results show that extra water in the
concrete mix plays a significant role. Also, longer curing time and
curing the concrete specimens at higher temperatures will result in
higher compressive strength.", keywords = "Fly ash, Geopolymer Concrete, Self-compactingconcrete, Self-compacting Geopolymer concrete", volume = "5", number = "2", pages = "64-7", }
