References
- Lemonis N, Tsakiridis PE, Katsiotis NS, et al. Hydration study of ternary blended cements containing ferronickel slag and natural pozzolan. Constr Build Mater. 2015;81:130–139.
- Wongsa A, Wongkvanklom A, Tanangteerapong D, et al. Comparative study of fire-resistant behaviors of high-calcium fly ash geopolymer mortar containing zeolite and mullite. J Sustain Cement-Based Mater. 2020.
- Khalifeh M, Saasen A, Vrålstad T, et al. Experimental study on the synthesis and characterization of aplite rock-based geopolymers. J Sustain Cement-Based Mater. 2016;5(4):233–246.
- El-Hassan H, Ismail N. Effect of process parameters on the performance of fly ash/GGBS blended geopolymer composites. J Sustain Cement-Based Mater. 2018;7(2):122–140.
- Ye J, Zhang W, Shi D. Performance evolutions of tailing-slag-based geopolymer under severe conditions. J Sustain Cement-Based Mater. 2015;4(2):101–115.
- Aboshia AMAA, Rahmat RA, Zain MFM, et al. Early age shrinkage cracking of restrained metakaolin-slag-palm oil fuel ash binder geopolymer mortars. J Sustain Cement-Based Mater. 2018;7(5):271–295.
- Maragkos I, Giannopoulou IP, Panias D. Synthesis of ferronickel slag-based geopolymers. Miner Eng. 2009;22(2):196–203.
- Zhang Z, Wang H, Provis JL. Quantitative study of the reactivity of fly ash in geopolymerization by FTIR. J Sustain Cement-Based Mater. 2012;1(4):154–166.
- Alvarez-Ayuso E, Querol X, Plana F, et al. Environmental, physical and structural characterisation of geopolymer matrixes synthesised from coal (co-)combustion fly ashes. J Hazard Mater. 2008;154(1-3):175–183.
- Huang Y, Wang Q, Shi M. Characteristics and reactivity of ferronickel slag powder. Constr Build Mater. 2017;156:773–789.
- Choi YC, Choi S. Alkali-silica reactivity of cementitious materials using ferro-nickel slag fine aggregates produced in different cooling conditions. Constr Build Mater. 2015;99:279–287.
- Saha AK, Sarker PK. Expansion due to alkali-silica reaction of ferronickel slag fine aggregate in OPC and blended cement mortars. Constr Build Mater. 2016;123:135–142.
- Saha AK, Sarker PK. Durability characteristics of concrete using ferronickel slag fine aggregate and fly ash. Mag Concr Res. 2018;70(17):865–874.
- Sun J, Feng J, Chen Z. Effect of ferronickel slag as fine aggregate on properties of concrete. Constr Build Mater. 2019;206:201–209.
- Saha AK, Sarker PK. Mechanical properties of concrete using ferronickel slag and fine aggregate and supplementary cementitious material. Concr Australia. 2018;44(4):40–44.
- Wang D, Wang Q, Zhuang S, et al. Evaluation of alkali-activated blast furnace ferronickel slag as a cementitious material: reaction mechanism, engineering properties and leaching behaviors. Constr Build Mater. 2018;188:860–873.
- Kim H, Lee CH, Ann KY. Feasibility of ferronickel slag powder for cementitious binder in concrete mix. Constr Build Mater. 2019;207:693–705.
- Chen Y, Ji T, Yang Z, et al. Sustainable use of ferronickel slag in cementitious composites and the effect on chloride penetration resistance. Constr Build Mater. 2020;240:117969.
- Komnitsas K, Yurramendi L, Bartzas G, et al. Factors affecting co-valorization of fayalitic and ferronickel slags for the production of alkali activated materials. Sci Total Environ. 2020;721:137753.
- Yang T, Zhang Z, Zhu H, et al. Re-examining the suitability of high magnesium nickel slag as precursors for alkali-activated materials. Constr Build Mater. 2019;213:109–120.
- Komnitsas K, Zaharaki D, Perdikatsis V. Geopolymerisation of low calcium ferronickel slags. J Mater Sci. 2007;42(9):3073–3082.
- Komnitsas K, Zaharaki D, Perdikatsis V. Effect of synthesis parameters on the compressive strength of low-calcium ferronickel slag inorganic polymers. J Hazard Mater. 2009;161(2-3):760–768.
- Komnitsas K, Zaharaki D, Bartzas G. Effect of sulphate and nitrate anions on heavy metal immobilisation in ferronickel slag geopolymers. Appl Clay Sci. 2013;73:103–109.
- Yang T, Yao X, Zhang Z. Geopolymer prepared with high-magnesium nickel slag: characterization of properties and microstructure. Constr Build Mater. 2014;59:188–194.
- Yang T, Wu Q, Zhu H, et al. Geopolymer with improved thermal stability by incorporating high-magnesium nickel slag. Constr Build Mater. 2017;155:475–484.
- Zhang Z, Zhu Y, Yang T, et al. Conversion of local industrial wastes into greener cement through geopolymer technology: a case study of high-magnesium nickel slag. J Clean Prod. 2017;141:463–471.
- Sakkas K, Nomikos P, Sofianos A, et al. Utilisation of FeNi-Slag for the production of inorganic polymeric materials for construction or for passive fire protection. Waste Biomass Valor. 2014;5(3):403–410.
- Bouaissi A, Li L, Abdullah MMAB, et al. Mechanical properties and microstructure analysis of FA-GGBS-HMNS based geopolymer concrete. Constr Build Mater. 2019;210:198–209.
- Saha AK, Sarker PK. Sustainable use of ferronickel slag fine aggregate and fly ash in structural concrete: mechanical properties and leaching study. J Clean Prod. 2017;162:438–448.
- Nath P, Sarker PK. Use of OPC to improve setting and early strength properties of low calcium fly ash geopolymer concrete cured at room temperature. Cem Concr Compos. 2015;55:205–214.
- American Society for Testing and Materials (ASTM). Standard test method for flow of hydraulic cement mortar. West Conshohocken (PA): ASTM; 2007. Standard No. ASTM C1437:2007.
- Australian Standards (AS). Methods of testing concrete method 9: compressive strength tests—concrete, mortar and grout specimens. Sydney, Australia: AS; 2014. Standard No. AS1012.9:2014.
- American Society for Testing and Materials (ASTM). Standard test method for density, absorption, and voids in hardened concrete. West Conshohocken (PA): ASTM; 2006. Standard No. ASTM C642:2006.
- American Society for Testing and Materials (ASTM). Standard test method for measurement of rate of absorption of water by hydraulic-cement concretes. West Conshohocken (PA): ASTM; 2004. Standard No. ASTM C1585:2004.
- Abràmofff MD, Magalhães PJ, Ram SJ. Image processing with ImageJ. Biophoton Int. 2005;11:36–43.
- Coelho AA. TOPAS and TOPAS-Academic: an optimization program integrating computer algebra and crystallographic objects written in C++. J Appl Crystallogr. 2018;51(1):210–218.
- Rietveld HM. A profile refinement method for nuclear and magnetic structures. J Appl Crystallogr. 1969;2(2):65–71.
- Hill RJ, Howard CJ. Quantitative phase analysis from neutron powder diffraction data using the Rietveld method. J Appl Crystallogr. 1987;20(6):467–474.
- Provis JL, Duxson P, van Deventer JSJ. The role of particle technology in developing sustainable construction materials. Adv Powder Technol. 2010;21(1):2–7.
- Khodr M, Law DW, Gunasekara C, et al. Compressive strength and microstructure evolution of low calcium brown coal fly ash-based geopolymer. J Sustain Cement-Based Mater. 2020;9(1):17–34.
- Yan S, Sagoe-Crentsil K. Evaluation of fly ash geopolymer mortar incorporating calcined wastepaper sludge. J Sustain Cement-Based Mater. 2016;5(6):370–380.
- Sathonsaowaphak A, Chindaprasirt P, Pimraksa K. Workability and strength of lignite bottom ash geopolymer mortar. J Hazard Mater. 2009;168(1):44–50.
- Yaseri S, Hajiaghaei G, Mohammadi F, et al. The role of synthesis parameters on the workability, setting and strength properties of binary binder based geopolymer paste. Constr Build Mater. 2017;157:534–545.
- Hardjito D. Studies of fly ash-based geopolymer concrete [Dissertation]. Perth, Australia: Curtin University; 2005.
- Abdalqader AF, Jin F, Al-Tabbaa A. Characterisation of reactive magnesia and sodium carbonate-activated fly ash/slag paste blends. Constr Build Mater. 2015;93:506–513.
- Chi M, Huang R. Binding mechanism and properties of alkali-activated fly ash/slag mortars. Constr Build Mater. 2013;40:291–298.
- Singh GVPB, Subramaniam KVL. Effect of active components on strength development in alkali-activated low calcium fly ash cements. J Sustain Cement-Based Mater. 2018;8(1):1–19.
- Pimraksa K, Chindaprasirt P, Rungchet A, et al. Lightweight geopolymer made of highly porous siliceous materials with various Na2O/Al2O3 and SiO2/Al2O3 ratios. Mater Sci Eng A. 2011;528(21):6616–6623.
- Phair JW, Van Deventer JSJ. Effect of the silicate activator pH on the microstructural characteristics of waste-based geopolymers. Int J Miner Process. 2002;66(1–4):121–143.
- Juengsuwattananon K, Winnefeld F, Chindaprasirt P, et al. Correlation between initial SiO2/Al2O3, Na2O/Al2O3, Na2O/SiO2 and H2O/Na2O ratios on phase and microstructure of reaction products of metakaolin-rice husk ash geopolymer. Constr Build Mater. 2019;226:406–417.
- Cheng Y, Hongqiang M, Hongyu C, et al. Preparation and characterization of coal gangue geopolymers. Constr Build Mater. 2018;187:318–326.
- Ruiz-Santaquiteria C, Skibsted J, Fernández-Jiménez A, et al. Alkaline solution/binder ratio as a determining factor in the alkaline activation of aluminosilicates. Cem Concr Res. 2012;42(9):1242–1251.
- Tho-In T, Sata V, Boonserm K, et al. Compressive strength and microstructure analysis of geopolymer paste using waste glass powder and fly ash. J Clean Prod. 2018;172:2892–2898.
- Steveson M, Sagoe-Crentsil K. Relationships between composition, structure and strength of inorganic polymers: part 2 Fly ash-derived inorganic polymers. J Mater Sci. 2005;40(16):4247–4259.
- Provis JL, Lukey GC, Van Deventer JSJ. Do geopolymers actually contain nanocrystalline zeolites? A reexamination of existing results. Chem. Mater. 2005;17(12):3075–3085.
- Duxson P, Fernández-Jiménez A, Provis JL, et al. Geopolymer technology: the current state of the art. J Mater Sci. 2007;42(9):2917–2933.
- Zaharaki D, Komnitsas K, Perdikatsis V. Use of analytical techniques for identification of inorganic polymer gel composition. J Mater Sci. 2010;45(10):2715–2724.