Utilization of Phosphorus Slag as Fly Ash Replacement in Low-Heat Portland Cement Blends: Comparative Study of Hydration Behaviors, Physical Properties, and Life-Cycle Assessment
暂无分享,去创建一个
[1] Junsong Chen,et al. Influence of main components of accelerators on mechanical property and hydration of Portland cement in a dry-hot geothermal environment , 2023, Construction and Building Materials.
[2] Jiazheng Li,et al. Hydration, microstructure characteristics, and mechanical properties of high-ferrite Portland cement in the presence of fly ash and phosphorus slag , 2023, Cement and Concrete Composites.
[3] Changyong Liu,et al. Effects of silica fume type and cementitious material content on the adiabatic temperature rise behavior of LHP cement concrete , 2022, Construction and Building Materials.
[4] Ting Luo,et al. Understanding the workability of alkali-activated phosphorus slag pastes: Effects of alkali dose and silicate modulus on early-age hydration reactions , 2022, Cement and Concrete Composites.
[5] Saddam Ali,et al. Early hydration and compressive strength of steam cured high-strength concrete based on simplex centroid design method , 2022, Case Studies in Construction Materials.
[6] C. Shi,et al. Compressive strength, water and chloride transport properties of early CO2-cured Portland cement-fly ash-slag ternary mortars , 2022, Cement and Concrete Composites.
[7] Penghuan Liu,et al. Study on fine-toned fly ash content for lightweight strain-hardening cementitious composites (LSHCC) with low fiber content , 2022, Construction and Building Materials.
[8] Jiazheng Li,et al. Roles of fly ash, granulated blast-furnace slag, and silica fume in long-term resistance to external sulfate attacks at atmospheric temperature , 2022, Cement and Concrete Composites.
[9] Xiaojian Gao,et al. Effect of carbonation curing on durability of cement mortar incorporating carbonated fly ash subjected to Freeze-Thaw and sulfate attack , 2022, Construction and Building Materials.
[10] B. Li,et al. Modification of phosphogypsum using circulating fluidized bed fly ash and carbide slag for use as cement retarder , 2022, Construction and Building Materials.
[11] Q. Yu,et al. Effects of ladle slag on Class F fly ash geopolymer: Reaction mechanism and high temperature behavior , 2022, Cement and Concrete Composites.
[12] W. Liao,et al. Microstructure and shrinkage behavior of high-performance concrete containing supplementary cementitious materials , 2021, Construction and Building Materials.
[13] Q. Yuan,et al. Rheological behaviour of low-heat Portland cement paste with MgO-based expansive agent and shrinkage reducing admixture , 2021 .
[14] Z. Hassankhani‐Majd,et al. Recovery of valuable materials from phosphorus slag using nitric acid leaching followed by precipitation method , 2021, Resources, Conservation and Recycling.
[15] Xiaobo Wang,et al. Resistance improvement of cement mortar containing silica fume to external sulfate attacks at normal temperature , 2020 .
[16] Guoxin Zhang,et al. Environmental impact and thermal cracking resistance of low heat cement (LHC) and moderate heat cement (MHC) concrete at early ages , 2020 .
[17] Shengwen Tang,et al. Comparison between the effects of phosphorous slag and fly ash on the C-S-H structure, long-term hydration heat and volume deformation of cement-based materials , 2020 .
[18] L. Divet,et al. Quantifying glass powder reaction in blended-cement pastes with the Rietveld-PONKCS method , 2020 .
[19] Jingwei Gong,et al. Optimization of mixture proportions in ternary low-heat Portland cement-based cementitious systems with mortar blends based on projection pursuit regression , 2020 .
[20] H.Q. Yang,et al. Environmental evaluation, hydration, pore structure, volume deformation and abrasion resistance of low heat Portland (LHP) cement-based materials , 2018, Journal of Cleaner Production.
[21] A. Fernández-Jiménez,et al. Rheology of activated phosphorus slag with lime and alkaline salts , 2018, Cement and Concrete Research.
[22] Shengwen Tang,et al. Energy saving benefit, mechanical performance, volume stabilities, hydration properties and products of low heat cement-based materials , 2018, Energy and Buildings.
[23] B. Li,et al. Comparison of the retarding mechanisms of sodium gluconate and amino trimethylene phosphonic acid on cement hydration and the influence on cement performance , 2018 .
[24] Q. Wang,et al. Influence of high-volume electric furnace nickel slag and phosphorous slag on the properties of massive concrete , 2018, Journal of Thermal Analysis and Calorimetry.
[25] P. Chindaprasirt,et al. Synthesis of low-temperature calcium sulfoaluminate-belite cements from industrial wastes and their hydration: Comparative studies between lignite fly ash and bottom ash , 2017 .
[26] C. Shi,et al. Drying shrinkage and cracking resistance of concrete made with ternary cementitious components , 2017 .
[27] Zengqi Zhang,et al. Hydration mechanisms of composite binders containing phosphorus slag at different temperatures , 2017 .
[28] B. Li,et al. The Performance and Mechanism Analysis of Cement Pastes Added to Aluminum Sulfate-Based Low-Alkali Setting Accelerator , 2017 .
[29] Jinqiang Hu. Comparison between the effects of superfine steel slag and superfine phosphorus slag on the long-term performances and durability of concrete , 2017, Journal of Thermal Analysis and Calorimetry.
[30] C. Shi,et al. Factorial Design Method for Designing Ternary Composite Cements to Mitigate ASR Expansion , 2016 .
[31] C. Shi,et al. The hydration and microstructure of ultra high-strength concrete with cement–silica fume–slag binder , 2015 .
[32] J. Sobhani,et al. Durability of copper slag contained concrete exposed to sulfate attack , 2011 .
[33] G. Saoût,et al. Hydration mechanisms of ternary Portland cements containing limestone powder and fly ash , 2011 .
[34] X. Chang,et al. Hydropower in China at present and its further development , 2010 .
[35] K. Gnandi,et al. The Geochemical Characterization of Mine Effluents from the Phosphorite Processing Plant of Kpémé (Southern Togo) , 2009 .
[36] K. Fang,et al. Anti-crack performance of phosphorus slag concrete , 2009, Wuhan University Journal of Natural Sciences.
[37] Xiaolin Lu,et al. Microstructure and pore structure of concrete mixed with superfine phosphorous slag and superplasticizer , 2008 .
[38] T. Nawa,et al. Effect of water curing conditions on the hydration degree and compressive strengths of fly ash–cement paste , 2006 .
[39] René Guyonnet,et al. EFFECT OF POLYSACCHARIDES ON THE HYDRATION OF CEMENT PASTE AT EARLY AGES , 2004 .
[40] Pero Dabić,et al. A conceptual model of the cement hydration process , 2000 .
[41] Dehuai Wang,et al. On predicting compressive strengths of mortars with ternary blends of cement, ggbfs and fly ash , 1997 .
[42] G. Pouskouleli,et al. Prediction of compressive strength of mortars made with portland cement - blast-furnace slag - fly ash blends , 1991 .
[43] Xiaohong Zhu,et al. Modification of water absorption and pore structure of high-volume fly ash cement pastes by incorporating nanosilica , 2021 .
[44] Harald Justnes,et al. Synergy between fly ash and limestone powder in ternary cements , 2011 .
[45] Prabir Sarker,et al. Effect of Fly Ash on the Durability Properties of High Strength Concrete , 2011 .
[46] Ge Xueliang. Study on dry shrinkage property of phosphorous slag concrete , 2010 .
[47] Hu Peng-gang. Study of Effect of Phosphorous Slag on Cement Concrete Performance and Mechanics Research , 2008 .
[48] S. Yan. EFFECTS OF PHOSPHORUS SLAG ON HYDRATION PROPERTIES AND PORE STRUCTURE OF CEMENT PASTE , 2007 .