Influence of activator type on hydration kinetics, hydrate assemblage and microstructural development of alkali activated blast-furnace slags
暂无分享,去创建一个
Frank Winnefeld | Barbara Lothenbach | G. Saoût | B. Lothenbach | Mohsen Ben Haha | F. Winnefeld | M. Ben Haha | G. Le Saout
[1] J. Deventer,et al. Understanding the relationship between geopolymer composition, microstructure and mechanical properties , 2005 .
[2] V. Zivica,et al. Effects of type and dosage of alkaline activator and temperature on the properties of alkali-activated slag mixtures , 2007 .
[3] B. Münch,et al. Quantification of hydration phases in supersulfated cements: review and new approaches , 2011 .
[4] Karen L. Scrivener,et al. Relation of expansion due to alkali silica reaction to the degree of reaction measured by SEM image analysis , 2007 .
[5] Francisca Puertas,et al. Effect of activator mix on the hydration and strength behaviour of alkali-activated slag cements , 2003 .
[6] F. P. Glasser,et al. The magnesia–silica gel phase in slag cements: alkali (K, Cs) sorption potential of synthetic gels , 2005 .
[7] J. I. Escalante-García,et al. Hydration Products and Reactivity of Blast‐Furnace Slag Activated by Various Alkalis , 2003 .
[8] P. Monteiro,et al. Structural Investigations of Alkali Silicate Gels , 2005 .
[9] J. Deventer,et al. Geopolymer technology: the current state of the art , 2007 .
[10] E. Kanezaki. Thermal behavior of the hydrotalcite-like layered structure of Mg and Al-layered double hydroxides with interlayer carbonate by means of in situ powder HTXRD and DTA/TG , 1998 .
[11] Rachel J. Detwiler,et al. Pore structure of plain cement pastes hydrated at different temperatures , 1990 .
[12] Barbara Lothenbach,et al. Quantification of the degree of reaction of fly ash , 2010 .
[13] J. Sharp,et al. The microstructure and mechanical properties of blended cements hydrated at various temperatures , 2001 .
[14] Francisca Puertas,et al. Pore solution in alkali-activated slag cement pastes. Relation to the composition and structure of calcium silicate hydrate , 2004 .
[15] Francisca Puertas,et al. Alkali-activated slag mortars: Mechanical strength behaviour , 1999 .
[16] K. Scrivener,et al. Effects of an early or a late heat treatment on the microstructure and composition of inner C-S-H products of Portland cement mortars , 2002 .
[17] Frank Winnefeld,et al. Hydration of alkali-activated slag: comparison with ordinary Portland cement , 2006 .
[18] Philip G. Malone,et al. Activation of Ground Blast‐Furnace Slag by Alkali‐Metal and Alkaline‐Earth Hydroxides , 1992 .
[19] J. Deventer,et al. The coexistence of geopolymeric gel and calcium silicate hydrate at the early stage of alkaline activation , 2005 .
[20] Francisca Puertas,et al. Setting of alkali-activated slag cement. Influence of activator nature , 2001 .
[21] K. Scrivener,et al. Quantitative study of Portland cement hydration by X-ray diffraction/rietveld analysis and independent methods , 2004 .
[22] J. Davidovits. Geopolymers and geopolymeric materials , 1989 .
[23] P. L. Pratt,et al. Factors affecting the strength of alkali-activated slag , 1994 .
[24] Shi Caijun,et al. Investigation on some factors affecting the characteristics of alkali-phosphorus slag cement , 1989 .
[25] C. Dobson,et al. The characterization of hardened alkali-activated blast-furnace slag pastes and the nature of the calcium silicate hydrate (C-S-H) phase , 1994 .
[26] K. Scrivener,et al. 29Si and 27Al NMR study of alkali-activated slag , 2003 .
[27] E. Gartner. Industrially interesting approaches to “low-CO2” cements ☆ , 2004 .
[28] H. Taylor. Proposed Structure for Calcium Silicate Hydrate Gel , 1986 .
[29] Karen L. Scrivener,et al. Backscattered electron imaging of cementitious microstructures: Understanding and quantification , 2004 .
[30] Mohsen Ben Haha. Mechanical effects of alkali silica reaction in concrete studied by SEM-image analysis , 2006 .
[31] L. Diamond,et al. Synthesis and characterization of the LDH hydrotalcite-pyroaurite solid-solution series , 2010 .
[32] I. Richardson. The nature of the hydration products in hardened cement pastes , 2000 .
[33] L. Black,et al. Cell Dimensions and Composition of Nanocrystalline Calcium Silicate Hydrate Solid Solutions. Part 1: Synchrotron-Based X-Ray Diffraction , 2008 .
[34] J. Russias,et al. Structural characterization of C–S–H and C–A–S–H samples—Part I: Long-range order investigated by Rietveld analyses , 2009 .
[35] F. Puertas,et al. Mineralogical and microstructural characterisation of alkali-activated fly ash/slag pastes , 2003 .
[36] I. Richardson. The calcium silicate hydrates , 2008 .
[37] Hamlin M. Jennings,et al. Pore solution chemistry of alkali-activated ground granulated blast-furnace slag , 1999 .
[38] J. Deventer,et al. The Role of Inorganic Polymer Technology in the Development of ‘Green Concrete’ , 2007 .
[39] P. Pochet. A Quantitative Analysis , 2006 .
[40] X. Cong,et al. Effects of the temperature and relative humidity on the structure of CSH gel , 1995 .
[41] K. Scrivener,et al. Hydration products of alkali activated slag cement , 1995 .
[42] B. Lothenbach,et al. Hydration of alkali-activated slag: thermodynamic modelling , 2007 .
[43] I. Richardson. Tobermorite/jennite- and tobermorite/calcium hydroxide-based models for the structure of C-S-H: applicability to hardened pastes of tricalcium silicate, β-dicalcium silicate, Portland cement, and blends of Portland cement with blast-furnace slag, metakaolin, or silica fume , 2004 .