Preparation of metakaolin based geopolymer and its three-dimensional pore structural characterization

Yunsheng Zhang; Wenhua Zhang; Wei Sun; Zongjin Li; Zhiyong Liu

doi:10.1007/s11595-015-1187-5

Journal of Wuhan University of Technology Materials Science Edition ›› 2015, Vol. 30 ›› Issue (3) : 550 -555. DOI: 10.1007/s11595-015-1187-5

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Preparation of metakaolin based geopolymer and its three-dimensional pore structural characterization

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Abstract

Three types of pure geopolymer pastes (poly-sialate PS, poly-sialate-siloxo PSS, and poly-sialate-siloxo PSDS) were first prepared by alkali (NaOH and KOH) activated metakaolin. Then a void space network was employed to simulate the 3-D pore-throat distribution across the unit cell of the various hardened geopolymer pastes with reference to their experimental mercury intrusion curves. Based on the simulated 3-D pore-throat structure models, a wide range of pore-level properties such as porosity, connectivity, permeability and tortuosity of various geopolymer pastes were calculated. The 3-D structural model and calculated parameters showed that most of the pores in Na-PS geopolymer paste was very small size pores ranging from 0 to 100 nm. A few very large pores were spread amongst the small pores, resulting in a very high penetration pressure, permeability resistance. Unlike Na-PS geopolymer paste, pore size with medium size of Na-PSS, K-PS and K-PSS geopolymer pastes distributed uniformly across the unit cell, and the size changes of adjacent pores in the 3 geopolymer pastes were little, producing higher penetration pressure, lower permeability, smaller connectivity and larger tortuosity. In contrast, pores in Na-PSDS and K-PSDS geopolymer pastes were relatively large and distributed concentratively, which caused samples to be easily penetrated by mercury, methane and nitrogen etc under relatively low pressures.

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polymer / simulation / porosity

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Yunsheng Zhang, Wenhua Zhang, Wei Sun, Zongjin Li, Zhiyong Liu. Preparation of metakaolin based geopolymer and its three-dimensional pore structural characterization. Journal of Wuhan University of Technology Materials Science Edition, 2015, 30(3): 550-555 DOI:10.1007/s11595-015-1187-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Davidovits J. Geopolymers and Geopolymeric Materials[J]. Journal of Thermal Analysis and Calorimetry, 1989, 35(2): 429-441.

[2]	Davidovits J. Geopolymer Chemistry and Properties[J]. Geopolymer, 1988, 88(1): 25-48.

[3]	Kinrade S D, Knight C T G, Pole D L, et al. Silicon-29 NMR Studies of Tetraalkylammonium Silicate Solutions. 1. Equilibria, ²⁹Si Chemical Shifts, and ²⁹Si Relaxation[J]. Inorganic chemistry, 1998, 37(17): 4 272-4 277.

[4]	Swaddle T W, Salerno J, Tregloan P A. Aqueous Aluminates, Silicates, and Aluminosilicates[J]. Chem. Soc. Rev., 1994, 23(5): 319-325.

[5]	Swaddle T W. Silicate Complexes of Aluminum (III) in Aqueous Systems[J]. Coordination Chemistry Reviews, 2001, 219: 665-686.

[6]	Harris R K, Samadi-Maybodi A, Smith W. The Incorporation of Aluminum into Silicate Ions in Alkaline Aqueous Solutions, Studied by Aluminum-27 nmr[J]. Zeolites, 1997, 19(2): 147-155.

[7]	Davidovits J. Geopolymer Cements to Minimise Carbon-dioxide Greenhouse-warming[J]. Ceram. Trans., 1993, 37: 165-182.

[8]	Alonso S, Palomo A. Calorimetric Study of Alkaline Activation of Calcium Hydroxide-metakaolin Solid Mixtures[J]. Cement and Concrete Research, 2001, 31(1): 25-30.

[9]	Alonso S, Palomo A. Alkaline Activation of Metakaolin and Calcium Hydroxide Mixtures: Influence of Ttemperature, Activator Concentration and Solids Ratio[J]. Materials Letters, 2001, 47(1): 55-62.

[10]	Davidovits J, Comrie D C, Paterson J H, et al. Geopolymeric Concretes for Environmental Protection[J]. Concrete International, 1990, 12(7): 30-39.

[11]	Van Jaarsveld J G S, Van Deventer J S J, Lorenzen L. The Potential Use of Geopolymeric Materials to Immobilise Toxic Metals: Part I. Theory and applications[J]. Minerals Engineering, 1997, 10(7): 659-669.

[12]	Lyon R E, Balaguru P N, Foden A, et al. Fire-resistant Aluminosilicate Composites[J]. Fire and Materials, 1997, 21(2): 67-73.

[13]	Palomo A, Blanco-Varela M T, Granizo M L, et al. Chemical Stability of Cementitious Materials Based on Metakaolin[J]. Cement and Concrete Research, 1999, 29(7): 997-1 004.

[14]	Yunsheng Z, Wei S, Zongjin L. Preparation and Microstructure of K-PSDS Geopolymeric Binder[J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2007, 302(1): 473-482.

[15]	Blunt M, King P. Relative Permeabilities from Two-and Three-dimensional Pore-scale Network Modelling[J]. Transport in Porous Media, 1991, 6(4): 407-433.

[16]	Blunt M, King P. Macroscopic Parameters from Simulations of Pore Scale Flow[J]. Physical Review A, 1990, 42(8): 4 780-4 787.

[17]	Spearing M, Matthews G P. Modelling Characteristic Properties of Sandstones[J]. Transport in Porous Media, 1991, 6(1): 71-90.

[18]	Matthews G P, Spearing M C. Measurement and Modelling of Diffusion, Porosity and Other Pore Level Characteristics of Sandstones[J]. Marine and petroleum geology, 1992, 9(2): 146-154.

[19]	Matthews G P, Moss A K, Spearing M C, et al. Network Calculation of Mercury Intrusion and Absolute Permeability in Sandstone and Other Porous Media[J]. Powder Technology, 1993, 76(1): 95-107.

[20]	Matthews G P, Moss A K, Ridgway C J. The Effects of Correlated Networks on Mercury Intrusion Simulations and Permeabilities of Sandstone and Other Porous Media[J]. Powder Technology, 1995, 83(1): 61-77.

[21]	Washburn E W. Note on a Method of Determining the Distribution of Pore Sizes in A Porous Material[J]. Proceedings of the National Academy of Sciences of the United States of America, 1921 115-116.

[22]	IIS7 internet information services[OL]. http://www.pore-cor.com

[23]	Wei S, Sun Z Y, Zongjin L. Preparation and Microstructure of Na-PSDS Geopolymeric Matrix[J]. Ceramics-Silikáty, 2009, 53(2): 88-97.

[24]	Yunsheng Z, Wei S, Zongjin L. Synthesis and Microstructural Characterization of Fully-reacted Potassium-poly (sialate-siloxo) Geopolymeric Cement Matrix[J]. ACI Materials Journal, 2008, 105(2): 156-164.

[25]	Zhang Yunsheng. Research on Structure Formation Mechanism and Properties of High Performance Geopolymer Concrete[D], 2004 Nanjing: Southeast University.