[4] KOUSHKBAGHI M, ALIPOUR P, TAHMOURESI B, et al. Influence of different monomer ratios and recycled concrete aggregate on mechanical properties and durability of geopolymer concretes［J］. Construction and Building Materials, 2019, 205: 519-528.

[5] SINGH N B, MIDDENDORF B. Geopolymers as an alternative to Portland cement: an overview［J］. Construction and Building Materials, 2020, 237: 117455.

[6] YI Y, ZHU D J, GUO S C, et al. A review on the deterioration and approaches to enhance the durability of concrete in the marine environment［J］. Cement and Concrete Composites, 2020, 113: 103695.

[7] JAKOBSEN U H, DE WEERDT K, GEIKER M R. Elemental zonation in marine concrete［J］. Cement and Concrete Research, 2016, 85: 12-27.

[9] FRANOIS R, LAURENS S, DEBY F. Corrosion and its consequences for reinforced concrete structures［M］. London: Elsevier, 2018: 1-41.

[10] LAMBERT P, PAGE C L, VASSIE P R W. Investigations of reinforcement corrosion. 2. Electrochemical monitoring of steel in chloride-contaminated concrete［J］. Materials and Structures, 1991, 24(5): 351-358.

[11] MANGAT P S, OJEDOKUN O O. Bound chloride ingress in alkali activated concrete［J］. Construction and Building Materials, 2019, 212: 375-387.

[13] HU Y H, LIU G N, YANG Y G, et al. A fluid-solid-chemical coupled fractal model for simulating concrete damage and reinforcement corrosion［J］. Chemical Engineering Journal, 2022, 442: 136045.

[14] LIU J, JIANG Z L, ZHAO Y L, et al. Chloride distribution and steel corrosion in a concrete bridge after long-term exposure to natural marine environment［J］. Materials, 2020, 13(17): 3900.

[15] PAGE C L. Mechanism of corrosion protection in reinforced concrete marine structures［J］. Nature, 1975, 258(5535): 514-515.

[16] GHODS P, BURKAN ISGOR O, BENSEBAA F, et al. Angle-resolved XPS study of carbon steel passivity and chloride-induced depassivation in simulated concrete pore solution［J］. Corrosion Science, 2012, 58: 159-167.

[17] XU L J, WU P G, ZHU X J, et al. Structural characteristics and chloride intrusion mechanism of passive film［J］. Corrosion Science, 2022, 207: 110563.

[18] ZHANG W L, FRANOIS R, CAI Y X, et al. Influence of artificial cracks and interfacial defects on the corrosion behavior of steel in concrete during corrosion initiation under a chloride environment［J］. Construction and Building Materials, 2020, 253: 119165.

[19] WANG X P, SHAO M H, YE C Q, et al. Study on effect of chloride ions on corrosion behavior of reinforcing steel in simulated polluted concrete pore solutions by scanning micro-reference electrode technique［J］. Journal of Electroanalytical Chemistry, 2021, 895: 115454.

[20] QIAN S Y, ZHANG J Y, QU D Y. Theoretical and experimental study of microcell and macrocell corrosion in patch repairs of concrete structures［J］. Cement and Concrete Composites, 2006, 28(8): 685-695.

[21] JI Y S, HU Y J, ZHANG L L, et al. Laboratory studies on influence of transverse cracking on chloride-induced corrosion rate in concrete［J］. Cement and Concrete Composites, 2016, 69: 28-37.

[22] SOLEIMANI S, GHODS P, ISGOR O B, et al. Modeling the kinetics of corrosion in concrete patch repairs and identification of governing parameters［J］. Cement and Concrete Composites, 2010, 32(5): 360-368.

[23] VALIPOUR M, SHEKARCHI M, GHODS P. Comparative studies of experimental and numerical techniques in measurement of corrosion rate and time-to-corrosion-initiation of rebar in concrete in marine environments［J］. Cement and Concrete Composites, 2014, 48: 98-107.

[24] LLISO-FERRANDO J R, GASCH I, MARTNEZ-IBERNN A, et al. Effect of macrocell currents on rebar corrosion in reinforced concrete structures exposed to a marine environment［J］. Ocean Engineering, 2022, 257: 111680.

[25] LI L Q, DONG S G, WANG W, et al. Study on interaction between macrocell and microcell in the early corrosion process of reinforcing steel in concrete［J］. Science China Technological Sciences, 2010, 53(5): 1285-1289.

[26] TAHRI W, HU X, SHI C J, et al. Review on corrosion of steel reinforcement in alkali-activated concretes in chloride-containing environments［J］. Construction and Building Materials, 2021, 293: 123484.

[31] JEE A A, PRADHAN B. Long term effect of chloride and sulfates concentration, and cation allied with sulfates on corrosion performance of steel-reinforced in concrete［J］. Journal of Building Engineering, 2022, 56: 104813.

[32] YANG J Y, YE X, JIANG C, et al. Effect of NaCl solution and simulated concrete pore solution environment on the efficiency of steel bar energized corrosion［J］. Materials, 2022, 15(19): 7040.

[33] YUAN Q, SHI C J, DE SCHUTTER G, et al. Chloride binding of cement-based materials subjected to external chloride environment: a review［J］. Construction and Building Materials, 2009, 23(1): 1-13.

[34] RAMACHANDRAN V S. Possible states of chloride in the hydration of tricalcium silicate in the presence of calcium chloride［J］.Matériaux et Construction, 1971, 4(1): 3-12.

[35] SHI C J, YUAN Q, HE F Q, et al. Transport and interactions of chlorides in cement-based materials［M］. London: CRC Press, 2019.

[36] YANG Z M, HAO H L, LU Y Y, et al. Effects of Cl- erosion conditions on Cl- binding properties of fly-ash-slag-based geopolymer［J］. Journal of Building Engineering, 2023, 67: 105907.

[39] LEY-HERNANDEZ A M, LAPEYRE J, COOK R, et al. Elucidating the effect of water-to-cement ratio on the hydration mechanisms of cement［J］. ACS Omega, 2018, 3(5): 5092-5105.

[41] WASSERMANN R, KATZ A, BENTUR A. Minimum cement content requirements: a must or a myth?［J］.Materials and Structures, 2009, 42(7): 973-982.

[42] TONG L Y, ZHAO J H, CHENG Z R. Chloride ion binding effect and corrosion resistance of geopolymer materials prepared with seawater and coral sand［J］. Construction and Building Materials, 2021, 309: 125126.

[43] YURDAKUL E, TAYLOR P C, CEYLAN H, et al. Effect of paste-to-voids volume ratio on the performance of concrete mixtures［J］. Journal of Materials in Civil Engineering, 2013, 25(12): 1840-1851.

[44] AMORIM N S, ANDRADE NETO J S, SANTANA H A, et al. Durability and service life analysis of metakaolin-based geopolymer concretes with respect to chloride penetration using chloride migration test and corrosion potential［J］. Construction and Building Materials, 2021, 287: 122970.

[46] ABDULLAH A, HUSSIN K, AL BAKRI ABDULLAH M M, et al. The effects of various concentrations of NaOH on the inter-particle gelation of a fly ash geopolymer aggregate［J］. Materials, 2021, 14(5): 1111.

[48] JIANG C H, GUO W W, CHEN H, et al. Effect of filler type and content on mechanical properties and microstructure of sand concrete made with superfine waste sand［J］. Construction and Building Materials, 2018, 192: 442-449.

[49] LENG F G, FENG N Q, LU X Y. An experimental study on the properties of resistance to diffusion of chloride ions of fly ash and blast furnace slag concrete［J］. Cement and Concrete Research, 2000, 30(6): 989-992.

[51] BODDY A, HOOTON R D, GRUBER K A. Long-term testing of the chloride-penetration resistance of concrete containing high-reactivity metakaolin［J］. Cement and Concrete Research, 2001, 31(5): 759-765.

[52] GUO Y Q, ZHANG T S, TIAN W L, et al. Physically and chemically bound chlorides in hydrated cement pastes: a comparison study of the effects of silica fume and metakaolin［J］. Journal of Materials Science, 2019, 54(3): 2152-2169.

[53] ZULKIFLY K, CHENG-YONG H, YUN-MING L, et al. Effect of phosphate addition on room-temperature-cured fly ash-metakaolin blend geopolymers［J］. Construction and Building Materials, 2021, 270: 121486.

[54] HAN Q Y, ZHANG P, WU J J, et al. Comprehensive review of the properties of fly ash-based geopolymer with additive of nano-SiO2［J］. Nanotechnology Reviews, 2022, 11(1): 1478-1498.

[55] FU C Q, YE H L, ZHU K Q, et al. Alkali cation effects on chloride binding of alkali-activated fly ash and metakaolin geopolymers［J］. Cement and Concrete Composites, 2020, 114: 103721.

[56] SOURADEEP G, KUA H W. Encapsulation technology and techniques in self-healing concrete［J］. Journal of Materials in Civil Engineering, 2016, 28(12): 04016165.

[57] YANG K, ZHONG M Q, MAGEE B, et al. Investigation of effects of Portland cement fineness and alkali content on concrete plastic shrinkage cracking［J］. Construction and Building Materials, 2017, 144: 279-290.

[58] YILMAZ A, DEGIRMENCI N. Possibility of using waste tire rubber and fly ash with Portland cement as construction materials［J］. Waste Management, 2009, 29(5): 1541-1546.

[59] LIANG J, ZHU H, CHEN L, et al. Rebar corrosion investigation in rubber aggregate concrete via the chloride electro-accelerated test［J］. Materials, 2019, 12(6): 862.

[60] BERROCAL C G, LUNDGREN K, LFGREN I. Corrosion of steel bars embedded in fibre reinforced concrete under chloride attack: state of the art［J］. Cement and Concrete Research, 2016, 80: 69-85.

[61] GANESAN N, ABRAHAM R, DEEPA R S. Durability characteristics of steel fibre reinforced geopolymer concrete［J］. Construction and Building Materials, 2015, 93: 471-476.

[62] RAJENDRAN M. Corrosion assessment of ferrocement element with nanogeopolymer for marine application［J］. Structural Concrete, 2021, 22(5): 2882-2894.

[63] COMBRINCK R, KAYONDO M, LE ROUX B D, et al. Effect of various liquid admixtures on cracking of plastic concrete［J］. Construction and Building Materials, 2019, 202: 139-153.

[64] HOLT E, LEIVO M. Cracking risks associated with early age shrinkage［J］. Cement and Concrete Composites, 2004, 26(5): 521-530.

[65] ZHANG L F, QIAN X Q, LAI J Y, et al. Effect of different wind speeds and sealed curing time on early-age shrinkage of cement paste［J］. Construction and Building Materials, 2020, 255: 119366.

[66] MOELICH G M, VAN ZYL J E, RABIE N, et al. The influence of solar radiation on plastic shrinkage cracking in concrete［J］. Cement and Concrete Composites, 2021, 123: 104182.

[67] NASIR M, BAGHABRA AL-AMOUDI O S, MASLEHUDDIN M. Effect of placement temperature and curing method on plastic shrinkage of plain and pozzolanic cement concretes under hot weather［J］. Construction and Building Materials, 2017, 152: 943-953.

[68] KHAN I, XU T F, CASTEL A, et al. Risk of early age cracking in geopolymer concrete due to restrained shrinkage［J］. Construction and Building Materials, 2019, 229: 116840.

[69] MAYHOUB O A, MOHSEN A, ALHARBI Y R, et al. Effect of curing regimes on chloride binding capacity of geopolymer［J］. Ain Shams Engineering Journal, 2021, 12(4): 3659-3668.

[70] LIN P, NING Z Y, SHI J, et al. Study on the gallery structure cracking mechanisms and cracking control in dam construction site［J］. Engineering Failure Analysis, 2021, 121: 105135.

[71] XUE X W, ZHOU J L, HUA X D, et al. Analysis of the generating and influencing factors of vertical cracking in abutments during construction［J］. Advances in Materials Science and Engineering, 2018, 2018: 1-13.

[73] HUANG J J. Effective chloride removal in reinforced concrete using electrochemical method in the presence of calcium nitrite［J］. International Journal of Electrochemical Science, 2016: 4667-4674.

[74] GEIKER M R, POLDER R B. Experimental support for new electro active repair method for reinforced concrete［J］. Materials and Corrosion, 2016, 67(6): 600-606.

[77] GUO B B, QIAO G F, LI Z M, et al. Impressed current cathodic protection of chloride-contaminated RC structures with cracking: a numerical study［J］. Journal of Building Engineering, 2021, 44: 102943.

[79] SHAN H Y, XU J X, WANG Z Y, et al. Electrochemical chloride removal in reinforced concrete structures: improvement of effectiveness by simultaneous migration of silicate ion［J］. Construction and Building Materials, 2016, 127: 344-352.

[80] FAN W J, MAO J H, JIN W L, et al. Repair effect of bidirectional electromigration rehabilitation on concrete structures at different durability deterioration stages［J］. Construction and Building Materials, 2020, 251: 118872.

[81] FENG G Y, JIN Z Q, ZHU D J, et al. Effect of seawater and various parameters on electro-deposition repairing cracks of reinforced concrete exposed to marine environment［J］. Journal of Advanced Concrete Technology, 2022, 20(9): 581-595.

[82] WU Z Y, YU H F, MA H Y, et al. Rebar corrosion in coral aggregate concrete: determination of chloride threshold by LPR［J］. Corrosion Science, 2020, 163: 108238.

[83] PYO S, KOH T, TAFESSE M, et al. Chloride-induced corrosion of steel fiber near the surface of ultra-high performance concrete and its effect on flexural behavior with various thickness［J］. Construction and Building Materials, 2019, 224: 206-213.

[84] CHEN X D, MING Y, FU F, et al. Numerical and empirical models for service life assessment of RC structures in marine environment［J］.International Journal of Concrete Structures and Materials, 2022, 16(1): 1-12.

[85] British Standards Institution. Products and systems for the protection and repair of concrete structures—definitions, requirements, quality control and evaluation of conformity—part 4: structural bonding: EN B. 1504-4［S］. London: British Standards Institution, 2004.

[86] IBRAHIM M, AL-GAHTANI A S, MASLEHUDDIN M, et al. Effectiveness of concrete surface treatmentmaterials in reducing chloride-induced reinforcement corrosion［J］. Construction and Building Materials, 1997, 11(7/8): 443-451.

[87] ORLIKOWSKI J, CEBULSKI S, DAROWICKI K. Electrochemical investigations of conductive coatings applied as anodes in cathodic protection of reinforced concrete［J］. Cement and Concrete Composites, 2004, 26(6): 721-728.

[88] BERTOLINI L, ELSENER B, PEDEFERRI P, et al. Corrosion of steel in concrete： prevention, diagnosis, repair［M］. Hoboken: John Wiley & Sons, 2013.

[89] ZENG Y Q, ZHU M, YUAN Y F, et al. Corrosion resistance of CoCrFeMnNi high entropy alloy compared with 2205 duplex stainless steel in a simulated concrete pore solution［J］. Journal of Materials Engineering and Performance, 2023: 1-14.

[90] LUO H, ZOU S W, CHEN Y H, et al. Influence of carbon on the corrosion behaviour of interstitial equiatomic CoCrFeMnNi high-entropy alloys in a chlorinated concrete solution［J］. Corrosion Science, 2020, 163: 108287.

[91] KAMDE D K, PILLAI R G. Corrosion initiation mechanisms and service life estimation of concrete systems with fusion-bonded-epoxy (FBE) coated steel exposed to chlorides［J］. Construction and Building Materials, 2021, 277: 122314.

[92] DEWI M S, SANCHAROEN P, KLOMJIT P, et al. Effects of zinc alloy layer on corrosion and service life of galvanized reinforcing steels in chloride-contaminated concrete［J］. Journal of Building Engineering, 2023, 68: 106153.

[93] XIONG S Y, HUANG X L, XU W N, et al. Corrosion and protection of galvanized steel in vegetation-growing concrete (II): coating protection［J］. Asia-Pacific Journal of Chemical Engineering, 2021, 16(6): e2702.

[94] BOLZONI F, BRENNA A, ORMELLESE M. Recent advances in the use of inhibitors to prevent chloride-induced corrosion in reinforced concrete［J］. Cement and Concrete Research, 2022, 154: 106719.

[95] DHOUIBI L, REFAIT P, TRIKI E, et al. Interactions between nitrites and Fe(II)-containing phases during corrosion of iron in concrete- simulating electrolytes［J］. Journal of Materials Science, 2006, 41(15): 4928-4936.

[96] ANN K Y, JUNG H S, KIM H S, et al. Effect of calcium nitrite-based corrosion inhibitor in preventing corrosion of embedded steel in concrete［J］. Cement and Concrete Research, 2006, 36(3): 530-535.

[97] STNOR T A, JUSTNES H. Anodic corrosion inhibitors against chloride induced corrosion of concrete rebars［J］. Advances in Applied Ceramics, 2011, 110(3): 131-136.

[98] BOLZONI F, COPPOLA L, GOIDANICH S, et al. Corrosion inhibitors in reinforced concrete structures. Part 1: preventative technique［J］. Corrosion Engineering, Science and Technology, 2004, 39(3): 219-228.

[99] GAIDIS J M. Chemistry of corrosion inhibitors［J］. Cement and Concrete Composites, 2004, 26(3): 181-189.

[100] KERN P, LANDOLT D. Adsorption of organic corrosion inhibitors on iron in the active and passive state. A replacement reaction between inhibitor and water studied with the rotating quartz crystal microbalance［J］. Electrochimica Acta, 2001, 47(4): 589-598.

[101] DHOUIBI L, TRIKI E, RAHARINAIVO A. The application of electrochemical impedance spectroscopy to determine the long-term effectiveness of corrosion inhibitors for steel in concrete［J］. Cement and Concrete Composites, 2002, 24(1): 35-43.

[102] KONDRATOVA I L, MONTES P, BREMNER T W. Natural marine exposure results for reinforced concrete slabs with corrosion inhibitors［J］. Cement and Concrete Composites, 2003, 25(4/5): 483-490.

[103] WANG W Y, SONG Z J, GUO M Z, et al. Employing ginger extract as an eco-friendly corrosion inhibitor in cementitious materials［J］. Construction and Building Materials, 2019, 228: 116713.