Chloride binding mechanism and free chloride reduction method of alkali-activated slag/fly ash mixed with seawater

[1]  Bassam A. Tayeh,et al.  Effect of modified nano‐titanium and fly ash on ultra‐high‐performance concrete properties , 2023, Structural Concrete.

[2]  B. Tayeh,et al.  The effect of clinker aggregate on acid resistance in prepacked geopolymers containing metakaolin and quartz powder in the presence of ground blast furnace slag , 2023, Journal of Building Engineering.

[3]  K. Van Tittelboom,et al.  New findings on the contribution of Mg-Al-NO3 layered double hydroxides to the hydration and chloride binding capacity of cement pastes , 2023, Cement and Concrete Research.

[4]  Z. Shui,et al.  Modification on the chloride binding capacity of alkali activated slag by applying calcium and aluminium containing phases , 2022, Construction and Building Materials.

[5]  B. Tayeh,et al.  Hemp fiber reinforced one-part alkali-activated composites with expanded perlite: Mechanical properties, microstructure analysis and high-temperature resistance , 2022, Construction and Building Materials.

[6]  Bassam A. Tayeh,et al.  Durability and mechanical properties of cement concrete comprising pozzolanic materials with alkali-activated binder: A comprehensive review , 2022, Case Studies in Construction Materials.

[7]  John L. Zhou,et al.  Chloride-binding capacity of cement-GGBFS-nanosilica composites under seawater chloride-rich environment , 2022, Construction and Building Materials.

[8]  B. Long,et al.  Characteristics of alkali-activated slag powder mixing with seawater: workability, hydration reaction kinetics and mechanism , 2022, Case Studies in Construction Materials.

[9]  V. Mechtcherine,et al.  Electrochemical oxidation of recycled carbon fibers for an improved interaction toward alkali-activated composites , 2022, Journal of Cleaner Production.

[10]  Bassam A. Tayeh,et al.  Shear Strength of Eco-Friendly Self-compacting Concrete Beams Containing Ground Granulated Blast Furnace Slag and Fly Ash as Cement Replacement , 2022, Case Studies in Construction Materials.

[11]  Bassam A. Tayeh,et al.  Sustainable utilization of red mud waste (bauxite residue) and slag for the production of geopolymer composites: A review , 2022, Case Studies in Construction Materials.

[12]  K. Scrivener,et al.  Insights on chemical and physical chloride binding in blended cement pastes , 2022, Cement and Concrete Research.

[13]  C. Shi,et al.  Chloride binding behavior of synthesized reaction products in alkali-activated slag , 2022, Composites Part B: Engineering.

[14]  G. de Schutter,et al.  A review: Reaction mechanism and strength of slag and fly ash-based alkali-activated materials , 2022, Construction and Building Materials.

[15]  K. Scrivener,et al.  Chloride sorption by C-S-H quantified by SEM-EDX image analysis , 2022, Cement and Concrete Research.

[16]  X. Wan,et al.  Solidification of chloride ions in alkali-activated slag , 2022, Construction and Building Materials.

[17]  B. Lothenbach,et al.  Stability of hydrotalcite (Mg-Al layered double hydroxide) in presence of different anions , 2022, Cement and Concrete Research.

[18]  H.K. Lee,et al.  Hydration properties of alkali-activated fly ash/slag binders modified by MgO with different reactivity , 2021, Journal of Building Engineering.

[19]  Deju Zhu,et al.  Determination of free chloride in seawater cement paste with low water-binder ratio , 2021 .

[20]  Jihui Zhao,et al.  Chloride ion binding effect and corrosion resistance of geopolymer materials prepared with seawater and coral sand , 2021, Construction and Building Materials.

[21]  Huanyu Li,et al.  Insights into the microstructure evolution of slag, fly ash and condensed silica fume in blended cement paste , 2021, Construction and Building Materials.

[22]  Surendra P. Shah,et al.  Application of layered double hydroxides (LDHs) in corrosion resistance of reinforced concrete-state of the art , 2021, Construction and Building Materials.

[23]  Bassam A. Tayeh,et al.  Fabrication of Thermal Insulation Geopolymer Bricks Using Ferrosilicon Slag and Alumina waste , 2021, Case Studies in Construction Materials.

[24]  D. Sheng,et al.  Development of sustainable concrete incorporating seawater: A critical review on cement hydration, microstructure and mechanical strength , 2021 .

[25]  B. Tayeh,et al.  Mechanical Properties of Silica Fume Modified High-Volume Fly Ash Rubberized Self-Compacting Concrete , 2021, Sustainability.

[26]  H. Ye,et al.  Sequestration and release of nitrite and nitrate in alkali-activated slag: A route toward smart corrosion control , 2021 .

[27]  L. Pedroti,et al.  Application of eco-friendly alternative activators in alkali-activated materials: A review , 2021 .

[28]  C. Fu,et al.  Alkali cation effects on chloride binding of alkali-activated fly ash and metakaolin geopolymers , 2020 .

[29]  Jae Hong Kim,et al.  Chloride-bearing characteristics of alkali-activated slag mixed with seawater: Effect of different salinity levels , 2020 .

[30]  Cheol-Min Yang,et al.  Hydration kinetics and products of MgO-activated blast furnace slag , 2020, Construction and Building Materials.

[31]  Tao Yang,et al.  Chloride and heavy metal binding capacities of hydrotalcite-like phases formed in greener one-part sodium carbonate-activated slag cements , 2020 .

[32]  Qiping Tan,et al.  Corrosion protection of steel by Mg-Al layered double hydroxides in simulated concrete pore solution: Effect of SO42- , 2020, Corrosion Science.

[33]  Liguo Wang,et al.  Improving the chloride binding capacity of cement paste by adding nano-Al2O3: The cases of blended cement pastes , 2020 .

[34]  C. Shi,et al.  Chloride binding of alkali-activated slag/fly ash cements , 2019, Construction and Building Materials.

[35]  F. Wu,et al.  Chloride binding capacity of LDHs with various divalent cations and divalent to trivalent cation ratios in different solutions , 2019, CrystEngComm.

[36]  Wei Sun,et al.  Quantification methods for chloride binding in Portland cement and limestone systems , 2019, Cement and Concrete Research.

[37]  Le Huang,et al.  Influence of activator composition on the chloride binding capacity of alkali-activated slag , 2019, Cement and Concrete Composites.

[38]  P. Mangat,et al.  Bound chloride ingress in alkali activated concrete , 2019, Construction and Building Materials.

[39]  O. Kayali,et al.  Chloride binding ability and the onset corrosion threat on alkali-activated GGBFS and binary blend pastes , 2018 .

[40]  Chiara Giosuè,et al.  Corrosion behaviour of bare and galvanized steel in geopolymer and Ordinary Portland Cement based mortars with the same strength class exposed to chlorides , 2018 .

[41]  Yunsheng Zhang,et al.  Modelling of diffusion behavior of ions in low-density and high-density calcium silicate hydrate , 2017 .

[42]  John L. Provis,et al.  Chloride-induced corrosion of steel rebars in simulated pore solutions of alkali-activated concretes , 2017 .

[43]  Xinyuan Ke,et al.  Uptake of chloride and carbonate by Mg-Al and Ca-Al layered double hydroxides in simulated pore solutions of alkali-activated slag cement , 2017 .

[44]  D. Hou,et al.  Chloride ions transport and adsorption in the nano-pores of silicate calcium hydrate: Experimental and molecular dynamics studies , 2016 .

[45]  C. Unluer,et al.  Improving the performance of reactive MgO cement-based concrete mixes , 2016 .

[46]  H. Lee,et al.  Influence of the slag content on the chloride and sulfuric acid resistances of alkali-activated fly ash/slag paste , 2016 .

[47]  J. Deventer,et al.  MgO content of slag controls phase evolution and structural changes induced by accelerated carbonation in alkali-activated binders , 2014 .

[48]  John L. Provis,et al.  Influence of fly ash on the water and chloride permeability of alkali-activated slag mortars and concretes , 2013 .

[49]  Chunhua Shen,et al.  Influence of metakaolin on pore structure-related properties and thermodynamic stability of hydrate phases of concrete in seawater environment , 2012 .

[50]  G. Saoût,et al.  Influence of slag chemistry on the hydration of alkali-activated blast-furnace slag — Part I: Effect of MgO , 2011 .

[51]  Á. Palomo,et al.  Compatibility studies between N-A-S-H and C-A-S-H gels. Study in the ternary diagram Na2O–CaO–Al2O3–SiO2–H2O , 2011 .

[52]  Y. Elakneswaran,et al.  Ion-cement hydrate interactions govern multi-ionic transport model for cementitious materials , 2010 .

[53]  Bassam A. Tayeh,et al.  Eggshell as a fine aggregate replacer with silica fume and fly ash addition in concrete: A sustainable approach , 2023, Case Studies in Construction Materials.

[54]  J. Deventer,et al.  Modification of phase evolution in alkali-activated blast furnace slag by the incorporation of fly ash , 2014 .

[55]  J. Provis Geopolymers and other alkali activated materials: why, how, and what? , 2014 .

[56]  A. Fernández-Jiménez,et al.  FTIR study of the sol–gel synthesis of cementitious gels: C–S–H and N–A–S–H , 2008 .