Micromechanical multiscale model for alkali activation of fly ash and metakaolin

The process of alkali activation of fly ash and metakaolin is examined in the view of micromechanics. Elasticity is predicted via semi-analytical homogenization methods, using a combination of intrinsic elastic properties obtained from nanoindentation, evolving volume fractions and percolation theory. A new quantitative model for volume fraction is formulated, distinguishing the evolution of unreacted aluminosilicate material, solid gel particles of N-A-S-H gel, and open porosity, which is partially filled with the activator. The stiffening of N-A-S-H gel is modeled by increasing the fraction of solid gel particles. Their packing density and intrinsic elasticity differ in N-A-S-H gels synthesized from both activated materials. Percolation theory helps to address the quasi-solid transition at early ages and explains a long setting time and the beneficial effect of thermal curing. The low ability of N-A-S-H gel to bind water chemically explains the high porosity of Ca-deficient activated materials. Micromechanical analysis matches well the elastic experimental data during the activation and elucidates important stages in the formation of the microstructure.

[1]  Vít Smilauer,et al.  Material and structural characterization of alkali activated low-calcium brown coal fly ash. , 2009, Journal of hazardous materials.

[2]  J. Deventer,et al.  Geopolymer technology: the current state of the art , 2007 .

[3]  W. Lutze,et al.  Kinetics of fly ash leaching in strongly alkaline solutions , 2011 .

[4]  Waltraud M. Kriven,et al.  The effect of alkali and Si/Al ratio on the development of mechanical properties of metakaolin-based geopolymers , 2007 .

[5]  F. Ulm,et al.  The nanogranular nature of C–S–H , 2007 .

[6]  Roman Lackner,et al.  A multiscale micromechanics model for the autogenous-shrinkage deformation of early-age cement-based materials , 2007 .

[7]  J. Deventer,et al.  Reaction mechanisms in the geopolymeric conversion of inorganic waste to useful products. , 2007, Journal of hazardous materials.

[8]  P. Rohatgi,et al.  Crystallinity and selected properties of fly ash particles , 2002 .

[9]  A. Zaoui Continuum Micromechanics: Survey , 2002 .

[10]  Kim S. Finnie,et al.  Influence of curing schedule on the integrity of geopolymers , 2007 .

[11]  J. Deventer,et al.  Understanding the relationship between geopolymer composition, microstructure and mechanical properties , 2005 .

[12]  K. MacKenzie,et al.  Synthesis and characterisation of materials based on inorganic polymers of alumina and silica: sodium polysialate polymers , 2000 .

[13]  Ángel Palomo,et al.  Alkali-activated fly ashes: A cement for the future , 1999 .

[14]  G. Scherer Structure and properties of gels , 1999 .

[15]  T. L. Brownyard,et al.  Studies of the Physical Properties of Hardened Portland Cement Paste , 1946 .

[16]  Fernando Pacheco-Torgal,et al.  Properties of tungsten mine waste geopolymeric binder , 2008 .

[17]  J.S.J. van Deventer,et al.  Geopolymerisation kinetics. 2. Reaction kinetic modelling , 2007 .

[18]  J. Deventer,et al.  Geopolymerisation kinetics. 1. In situ energy-dispersive X-ray diffractometry , 2007 .

[19]  M. Jirásek,et al.  Meso-scale approach to modelling the fracture process zone of concrete subjected to uniaxial tension , 2009, 0901.4636.

[20]  K. Tanaka,et al.  Average stress in matrix and average elastic energy of materials with misfitting inclusions , 1973 .

[21]  Vít Šmilauer,et al.  Nanoindentation characteristics of alkali-activated aluminosilicate materials , 2011 .

[22]  J.S.J. van Deventer,et al.  The potential use of geopolymeric materials to immobilise toxic metals: Part I. Theory and applications☆ , 1997 .

[23]  Fernando Pacheco-Torgal,et al.  Alkali-activated binders: A review: Part 1. Historical background, terminology, reaction mechanisms and hydration products , 2008 .

[24]  Ángel Palomo,et al.  Composition and Microstructure of Alkali Activated Fly Ash Binder: Effect of the Activator , 2005 .

[25]  Á. Palomo,et al.  Alkali activation of fly ash. Part III: Effect of curing conditions on reaction and its graphical description , 2010 .

[26]  Vít S˘milauer,et al.  Microstructure-based micromechanical prediction of elastic properties in hydrating cement paste , 2006 .

[27]  E. Garboczi,et al.  Mapping drying shrinkage deformations in cement-based materials , 1997 .

[28]  P. Chindaprasirt,et al.  Compressive strength, modulus of elasticity, and water permeability of inorganic polymer concrete , 2010 .

[29]  Ángel Palomo,et al.  Alkali-activated fly ash: Effect of thermal curing conditions on mechanical and microstructural development – Part II , 2007 .

[30]  W. Lutze,et al.  Kinetics of fly ash geopolymerization , 2011 .

[31]  Rodney Hill,et al.  Theory of mechanical properties of fibre-strengthened materials—III. self-consistent model , 1965 .

[32]  Michal Šejnoha,et al.  Micromechanical modeling of imperfect textile composites , 2008 .

[33]  H. Rahier,et al.  Low-temperature synthesized aluminosilicate glasses Part IV Modulated DSC study on the effect of particle size of metakaolinite on the production of inorganic polymer glasses , 2003 .

[34]  Á. Palomo,et al.  Microstructure Development of Alkali-Activated Fly Ash Cement: A Descriptive Model , 2005 .

[35]  T. C. Powers,et al.  Structure and Physical Properties of Hardened Portland Cement Paste , 1958 .

[36]  Hamlin M. Jennings,et al.  Refinements to colloid model of C-S-H in cement: CM-II , 2008 .

[37]  Franz-Josef Ulm,et al.  A multiscale micromechanics-hydration model for the early-age elastic properties of cement-based materials , 2003 .