[1] [1] NIE Song, ZHOU Jian, XU Mingfeng, et al. Mater Rep, 2024, 38(2): 1-19.

[2] [2] SHI C J, QU B, PROVIS J L. Recent progress in low-carbon binders[J]. Cem Concr Res, 2019, 122: 227-250.

[3] [3] YAN Peiyu. J Chin Ceram Soc, 2022, 50(8): 2067-2069.

[4] [4] ZHONG H, ZHANG M Z. Engineered geopolymer composites: A state-of-the-art review[J]. Cem Concr Compos, 2023, 135: 104850.

[5] [5] TAHRI W, HU X, SHI C J, et al. Review on corrosion of steel reinforcement in alkali-activated concretes in chloride-containing environments[J]. Constr Build Mater, 2021, 293: 123484.

[6] [6] RUNCI A, PROVIS J L, SERDAR M. Revealing corrosion parameters of steel in alkali-activated materials[J]. Corros Sci, 2023, 210: 110849.

[7] [7] FERNáNDEZ-JIMéNEZ A, PALOMO A, CRIADO M. Microstructure development of alkali-activated fly ash cement: A descriptive model[J]. Cem Concr Res, 2005, 35(6): 1204-1209.

[8] [8] BASTIDAS D M, FERNáNDEZ-JIMéNEZ A, PALOMO A, et al. A study on the passive state stability of steel embedded in activated fly ash mortars[J]. Corros Sci, 2008, 50(4): 1058-1065.

[9] [9] TITTARELLI F, MOBILI A, GIOSUè C, 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[J]. Corros Sci, 2018, 134: 64-77.

[10] [10] ZHANG Z M, CHEN R, HU J, et al. Corrosion behavior of the reinforcement in chloride-contaminated alkali-activated fly ash pore solution[J]. Compos B Eng, 2021, 224: 109215.

[11] [11] MONTICELLI C, NATALI M E, BALBO A, et al. Corrosion behavior of steel in alkali-activated fly ash mortars in the light of their microstructural, mechanical and chemical characterization[J]. Cem Concr Res, 2016, 80: 60-68.

[12] [12] CRIADO M, MONTICELLI C, FAJARDO S, et al. Organic corrosion inhibitor mixtures for reinforcing steel embedded in carbonated alkali-activated fly ash mortar[J]. Constr Build Mater, 2012, 35: 30-37.

[13] [13] ORMELLESE M, BOLZONI F, LAZZARI L, et al. Organic substances as inhibitors for chloride-induced corrosion in reinforced concrete[J]. Mater Corros, 2011, 62(2): 170-177.

[14] [14] JOHARI M, ALLAHKARAM S R, TEYMOURI F, et al. The effect of carboxylate compounds on controlling nitrite’s environmental side effects for carbon steel corrosion protection in the simulated concrete pore solution[J]. Constr Build Mater, 2021, 308: 125037.

[15] [15] DIAMANTI M V, PéREZ ROSALES E A, RAFFAINI G, et al. Molecular modelling and electrochemical evaluation of organic inhibitors in concrete[J]. Corros Sci, 2015, 100: 231-241.

[16] [16] ORMELLESE M, LAZZARI L, GOIDANICH S, et al. A study of organic substances as inhibitors for chloride-induced corrosion in concrete[J]. Corros Sci, 2009, 51(12): 2959-2968.

[17] [17] LIU Y, HUANG L, LI M Y, et al. The effects of sodium citrate on compressive strength and paste microstructure of self-compacting concrete[J]. Constr Build Mater, 2020, 260: 120467.

[18] [18] MA C, FAN L L, SHI J Y, et al. Direct electric curing in high early-strength sodium citrate-doped Portland cement systems for sustainable energy saving applications[J]. Appl Energy, 2023, 347: 121381.

[19] [19] MONTICELLI C, NATALI M E, BALBO A, et al. A study on the corrosion of reinforcing bars in alkali-activated fly ash mortars under wet and dry exposures to chloride solutions[J]. Cem Concr Res, 2016, 87: 53-63.

[20] [20] TEYMOURI F, ALLAHKARAM S R, SHEKARCHI M, et al. A comprehensive study on the inhibition behaviour of four carboxylate-based corrosion inhibitors focusing on efficiency drop after the optimum concentration for carbon steel in the simulated concrete pore solution[J]. Constr Build Mater, 2021, 296: 123702.

[21] [21] MA Qi, CAI Jingshun, MU Song, et al. J Chin Ceram Soc, 2021, 49(5): 939-947.

[22] [22] ZHOU X C, YAO N, SHI J J. Unraveling electrochemical performance of a 10CrMo steel in alkaline concrete pore solutions with red mud and ground granulated blast-furnace slag[J]. Corros Sci, 2022, 207: 110568.

[23] [23] CUI L, HANG M Y, HUANG H H, et al. Experimental study on multi-component corrosion inhibitor for steel bar in chloride environment[J]. Constr Build Mater, 2021, 313: 125533.

[24] [24] XIAO Y, TANG J L, WANG Y Y, et al. Corrosion behavior of 2205 duplex stainless steel in NaCl solutions containing sulfide ions[J]. Corros Sci, 2022, 200: 110240.

[25] [25] CHEN R, HU J, MA Y W, et al. Characterization of the passive film formed on the reinforcement surface in alkali activated fly ash: Surface analysis and electrochemical evaluation[J]. Corros Sci, 2020, 165: 108393.

[26] [26] CHAN-ROSADO G, PECH-CANUL M A. Influence of native oxide film age on the passivation of carbon steel in neutral aqueous solutions with a dicarboxylic acid[J]. Corros Sci, 2019, 153: 19-31.

[27] [27] JIANG S B, JIANG L H, WANG Z Y, et al. Deoxyribonucleic acid as an inhibitor for chloride-induced corrosion of reinforcing steel in simulated concrete pore solutions[J]. Constr Build Mater, 2017, 150: 238-247.

[28] [28] ZHOU X C, LI M, GUAN X D, et al. Insights into the enhanced corrosion resistance of carbon steel in a novel low-carbon concrete with red mud and phytic acid[J]. Corros Sci, 2023, 211: 110903.