[3] [3] ROYCHAND R, GRAVINA R J, ZHUGE Y, et al. A comprehensive review on the mechanical properties of waste tire rubber concrete[J]. Construction and Building Materials, 2020, 237: 117651.

[4] [4] LI X M, LING T C, MO K H. Functions and impacts of plastic/rubber wastes as eco-friendly aggregate in concrete: a review[J]. Construction and Building Materials, 2020, 240: 117869.

[8] [8] KARIMI H R, ALIHA M R M, KHEDRI E, et al. Strength and cracking resistance of concrete containing different percentages and sizes of recycled tire rubber granules[J]. Journal of Building Engineering, 2023, 67: 106033.

[10] [10] ZHANG Y, LI Z, WU X. Effects of rubber powder on properties of concrete[J]. Construction and Building Materials, 2018, 187: 1125-1134.

[11] [11] LI J, XIAO H. Durability and mechanical properties of concrete with rubber powder[J]. Journal of Cleaner Production, 2020, 250: 119490.

[12] [12] YU Z P, TANG R, LI F R, et al. Experimental study and failure criterion analysis on combined compression-shear performance of rubber concrete (RC) with different rubber replacement ratio[J]. Construction and Building Materials, 2021, 288: 123105.

[14] [14] KANG J T, LIU Y S, YUAN J L, et al. Effectiveness of surface treatment on rubber particles towards compressive strength of rubber concrete: a numerical study on rubber-cement interface[J]. Construction and Building Materials, 2022, 350: 128820.

[15] [15] ASSAGGAF R, MASLEHUDDIN M, AL-OSTA M A, et al. Properties and sustainability of treated crumb rubber concrete[J]. Journal of Building Engineering, 2022, 51: 104250.

[16] [16] LIU M Y, LU J, JIANG W H, et al. Study on fatigue damage and fatigue crack propagation of rubber concrete[J]. Journal of Building Engineering, 2023, 65: 105718.

[17] [17] DI MUNDO R, PETRELLA A, NOTARNICOLA M. Surface and bulk hydrophobic cement composites by tyre rubber addition[J]. Construction and Building Materials, 2018, 172: 176-184.

[19] [19] ASSAGGAF R A, MASLEHUDDIN M, AL-DULAIJAN S U, et al. Cost-effective treatment of crumb rubber to improve the properties of crumb-rubber concrete[J]. Case Studies in Construction Materials, 2022, 16: e00881.

[20] [20] AGRAWAL D, WAGHE U, ANSARI K, et al. Experimental effect of pre-treatment of rubber fibers on mechanical properties of rubberized concrete[J]. Journal of Materials Research and Technology, 2023, 23: 791-807.

[21] [21] NAJIM K B, HALL M R. Crumb rubber aggregate coatings/pre-treatments and their effects on interfacial bonding, air entrapment and fracture toughness in self-compacting rubberised concrete (SCRC)[J]. Materials and Structures, 2013, 46(12): 2029-2043.

[22] [22] YOUSSF O, HASSANLI R, MILLS J, et al. Influence of mixing procedures, rubber treatment, and fibre additives on rubcrete performance[J]. Journal of Composites Science, 2019, 3(2): 41.

[23] [23] ROYCHAND R, GRAVINA R J, ZHUGE Y, et al. Practical rubber pre-treatment approch for concrete use: an experimental study[J]. Journal of Composites Science, 2021, 5(6): 143.

[24] [24] LI Y, YANG X B, LOU P, et al. Sulfate attack resistance of recycled aggregate concrete with NaOH-solution-treated crumb rubber[J]. Construction and Building Materials, 2021, 287: 123044.

[25] [25] YU J, ZHENG H P, HOU D S, et al. Silane coupling agent modification treatment to improve the properties of rubber-cement composites[J]. ACS Sustainable Chemistry & Engineering, 2021, 9(38): 12899-12911.

[26] [26] AGHAMOHAMMADI O, MOSTOFINEJAD D, ABTAHI S M. Effects of surface modification of crumb rubber with polyvinyl acetate on rubberized concrete[J]. ACI Materials Journal, 2022, 119(1): 195-206.

[27] [27] YU J, WANG N, WANG M H, et al. Recyclable rubber-cement composites produced by interfacial strengthened strategy from polyvinyl alcohol[J]. Construction and Building Materials, 2020, 264: 120541.

[28] [28] XU M H, XUE H, TIN W Y, et al. Synergistic effect by polyethylene glycol as interfacial modifier in silane-modified silica-reinforced composites[J]. Polymers, 2021, 13(5): 788.

[29] [29] HE L, CAI H D, HUANG Y, et al. Research on the properties of rubber concrete containing surface-modified rubber powders[J]. Journal of Building Engineering, 2021, 35: 101991.

[30] [30] RIVAS-VZQUEZ L P, SUREZ-ORDUA R, HERNNDEZ-TORRES J, et al. Effect of the surface treatment of recycled rubber on the mechanical strength of composite concrete/rubber[J]. Materials and Structures, 2015, 48(9): 2809-2814.

[31] [31] LI G Y, WANG Z K, LEUNG C K Y, et al. Properties of rubberized concrete modified by using silane coupling agent and carboxylated SBR[J]. Journal of Cleaner Production, 2016, 112: 797-807.

[32] [32] HE L, MA Y, LIU Q T, et al. Surface modification of crumb rubber and its influence on the mechanical properties of rubber-cement concrete[J]. Construction and Building Materials, 2016, 120: 403-407.

[33] [33] CHOU L H, YANG C K, LEE M T, et al. Effects of partial oxidation of crumb rubber on properties of rubberized mortar[J]. Composites Part B: Engineering, 2010, 41(8): 613-616.

[34] [34] JING Y, ZHANG C W, LIN G Y, et al. Studies on the mechanical properties of rubber concrete reinforced with high-temperature stirred pretreated waste rubber particles[J]. Construction and Building Materials, 2024, 440: 137516.

[35] [35] MUOZ-SNCHEZ B, ARVALO-CABALLERO M J, PACHECO-MENOR M C. Influence of acetic acid and calcium hydroxide treatments of rubber waste on the properties of rubberized mortars[J]. Materials and Structures, 2016, 50(1): 75.

[36] [36] LEUNG C K, GRASLEY Z C. Effect of micrometric and nanometric viscoelastic inclusions on mechanical damping behavior of cementitious composites[J]. Construction and Building Materials, 2012, 35: 444-451.

[37] [37] OSSOLA G, WOJCIK A. UV modification of tire rubber for use in cementitious composites[J]. Cement and Concrete Composites, 2014, 52: 34-41.

[38] [38] MARTNEZ-BARRERA G, DEL COZ-DAZ J J, LVAREZ-RABANAL F P, et al. Waste tire rubber particles modified by gamma radiation and their use as modifiers of concrete[J]. Case Studies in Construction Materials, 2020, 12: e00321.

[39] [39] ABD-ELAAL E S, ARABY S, MILLS J E, et al. Novel approach to improve crumb rubber concrete strength using thermal treatment[J]. Construction and Building Materials, 2019, 229: 116901.

[40] [40] BISHT K, RAMANA P V. Evaluation of mechanical and durability properties of crumb rubber concrete[J]. Construction and Building Materials, 2017, 155: 811-817.

[41] [41] REN F M, MO J X, WANG Q, et al. Crumb rubber as partial replacement for fine aggregate in concrete: an overview[J]. Construction and Building Materials, 2022, 343: 128049.

[42] [42] GHENI A A, ELGAWADY M A, MYERS J J. Mechanical characterization of concrete masonry units manufactured with crumb rubber aggregate[J]. ACI Materials Journal, 2017, 114(1): 65-76.

[43] [43] BIDECI A, ZTRK H, BIDECI S, et al. Fracture energy and mechanical characteristics of self-compacting concretes including waste bladder tyre[J]. Construction and Building Materials, 2017, 149: 669-678.

[44] [44] BRAVO M, DE BRITO J. Concrete made with used tyre aggregate: durability-related performance[J]. Journal of Cleaner Production, 2012, 25: 42-50.

[45] [45] ZHANG R, WANG H X, JI J, et al. Influences of different modification methods on surface activation of waste tire rubber powder applied in cement-based materials[J]. Construction and Building Materials, 2022, 314: 125191.

[46] [46] THOMAS B S, CHANDRA GUPTA R. Properties of high strength concrete containing scrap tire rubber[J]. Journal of Cleaner Production, 2016, 113: 86-92.

[47] [47] ELSAYED M, TAYEH B A, TAHA Y, et al. Experimental investigation on the behaviour of crumb rubber concrete columns exposed to chloride-sulphate attack[J]. Structures, 2022, 46: 246-264.

[48] [48] THOMAS B S, GUPTA R C. Long term behaviour of cement concrete containing discarded tire rubber[J]. Journal of Cleaner Production, 2015, 102: 78-87.

[49] [49] GIRSKAS G, NAGROCKIEN D. Crushed rubber waste impact of concrete basic properties[J]. Construction and Building Materials, 2017, 140: 36-42.

[50] [50] AN J L, YU Y, JIN Z Q, et al. Experimental and simulation study on capillary water absorption of modified crumb rubber concrete with steam-cured[J]. Journal of Building Engineering, 2023, 73: 106756.

[52] [52] ALWI ASSAGGAF R, UTHMAN AL-DULAIJAN S, MASLEHUDDIN M, et al. Effect of different treatments of crumb rubber on the durability characteristics of rubberized concrete[J]. Construction and Building Materials, 2022, 318: 126030.

[53] [53] MOHAMMADI I, KHABBAZ H. Shrinkage performance of crumb rubber concrete (CRC) prepared by water-soaking treatment method for rigid pavements[J]. Cement and Concrete Composites, 2015, 62: 106-116.

[54] [54] YUNG W H, YUNG L C, HUA L H. A study of the durability properties of waste tire rubber applied to self-compacting concrete[J]. Construction and Building Materials, 2013, 41: 665-672.

[55] [55] SI R Z, WANG J Q, GUO S C, et al. Evaluation of laboratory performance of self-consolidating concrete with recycled tire rubber[J]. Journal of Cleaner Production, 2018, 180: 823-831.

[56] [56] APPANA P M, MOHAMMED B S, ABDULKADIR I, et al. Mechanical, microstructural and drying shrinkage properties of NaOH-pretreated crumb rubber concrete: rsm-based modeling and optimization[J]. Materials, 2022, 15(7): 2588.

[57] [57] LI D D, ZHUGE Y, GRAVINA R, et al. Creep and drying shrinkage behaviour of crumb rubber concrete (CRC)[J]. Australian Journal of Civil Engineering, 2020, 18(2): 187-204.

[58] [58] SUKONTASUKKUL P, TIAMLOM K. Expansion under water and drying shrinkage of rubberized concrete mixed with crumb rubber with different size[J]. Construction and Building Materials, 2012, 29: 520-526.

[59] [59] YU Y, ZHU H. Influence of rubber size on properties of crumb rubber mortars[J]. Materials, 2016, 9(7): 527.

[60] [60] SU P F, DAI Q L, LI M M, et al. Investigation of the mechanical and shrinkage properties of plastic-rubber compound modified cement mortar with recycled tire steel fiber[J]. Construction and Building Materials, 2022, 334: 127391.

[61] [61] YOUNIS K H, NAJI H S, NAJIM K B. Cracking tendency of self-compacting concrete containing crumb rubber as fine aggregate[J]. Key Engineering Materials, 2017, 744: 55-60.

[62] [62] HALL M R, NAJIM K B. Structural behaviour and durability of steel-reinforced structural plain/self-compacting rubberised concrete (PRC/SCRC)[J]. Construction and Building Materials, 2014, 73: 490-497.

[63] [63] HUA L X, XIAO F P, LI Y T, et al. A potential damage mechanism of rubberized cement under freeze-thaw cycle[J]. Construction and Building Materials, 2020, 252: 119054.

[64] [64] SUN S, HAN X Y, CHEN A J, et al. Experimental analysis and evaluation of the compressive strength of rubberized concrete during freeze-thaw cycles[J]. International Journal of Concrete Structures and Materials, 2023, 17(1): 28.

[67] [67] GESOLU M, GNEYISI E, KHOSHNAW G, et al. Abrasion and freezing-thawing resistance of pervious concretes containing waste rubbers[J]. Construction and Building Materials, 2014, 73: 19-24.

[68] [68] GRINYS A, AUGONIS A, DAUKYS M, et al. Mechanical properties and durability of rubberized and SBR latex modified rubberized concrete[J]. Construction and Building Materials, 2020, 248: 118584.

[69] [69] BARICEVIC A, PEZER M, JELCIC RUKAVINA M, et al. Effect of polymer fibers recycled from waste tires on properties of wet-sprayed concrete[J]. Construction and Building Materials, 2018, 176: 135-144.

[70] [70] PHAM N P, TOUMI A, TURATSINZE A. Effect of an enhanced rubber-cement matrix interface on freeze-thaw resistance of the cement-based composite[J]. Construction and Building Materials, 2019, 207: 528-534.

[71] [71] DOU Y M, FENG G Y, XU L F, et al. Modification of rubber particles and its application in rubberized concrete[J]. Journal of Building Engineering, 2022, 51: 104346.

[72] [72] RICHARDSON A, COVENTRY K, EDMONDSON V, et al. Crumb rubber used in concrete to provide freeze-thaw protection (optimal particle size)[J]. Journal of Cleaner Production, 2016, 112: 599-606.

[73] [73] SHI J C, ZHAO L, HAN C, et al. The effects of silanized rubber and nano-SiO2 on microstructure and frost resistance characteristics of concrete using response surface methodology (RSM)[J]. Construction and Building Materials, 2022, 344: 128226.

[74] [74] GONEN T. Freezing-thawing and impact resistance of concretes containing waste crumb rubbers[J]. Construction and Building Materials, 2018, 177: 436-442.

[75] [75] ALSAIF A, BERNAL S A, GUADAGNINI M, et al. Freeze-thaw resistance of steel fibre reinforced rubberised concrete[J]. Construction and Building Materials, 2019, 195: 450-458.

[76] [76] WANG F C, PING X W, ZHOU J H, et al. Effects of crumb rubber on the frost resistance of cement-soil[J]. Construction and Building Materials, 2019, 223: 120-132.

[77] [77] ASSAGGAF R A, ALI M R, AL-DULAIJAN S U, et al. Properties of concrete with untreated and treated crumb rubber: a review[J]. Journal of Materials Research and Technology, 2021, 11: 1753-1798.

[78] [78] PHAM T M, ELCHALAKANI M, HAO H, et al. Durability characteristics of lightweight rubberized concrete[J]. Construction and Building Materials, 2019, 224: 584-599.

[79] [79] MALLEK J, DAOUD A, OMIKRINE-METALSSI O, et al. Performance of self-compacting rubberized concrete against carbonation and chloride penetration[J]. Structural Concrete, 2021, 22(5): 2720-2735.

[80] [80] THOMAS B S, GUPTA R C, MEHRA P, et al. Performance of high strength rubberized concrete in aggressive environment[J]. Construction and Building Materials, 2015, 83: 320-326.

[81] [81] MOHD NASIR N A, ABU BAKAR N, SAFIEE N A, et al. Permeation-durability properties of metakaolin blended concrete containing rubber[J]. European Journal of Environmental and Civil Engineering, 2022, 26(11): 5113-5128.

[82] [82] GUPTA T, SHARMA R, CHAUDHARY S. Influence of waste tyre fibers on strength, abrasion resistance and carbonation of concrete[J]. Scientia Iranica, 2015, 22: 1481-1489.

[83] [83] MARIA DA SILVA F, BATISTA L S, GACHET L A, et al. The effect of tire-rubber pretreatment on the physical-mechanical properties and durability of high-performance concrete[J]. Journal of Materials in Civil Engineering, 2022, 34(12): 04022354.

[84] [84] GUPTA T, SIDDIQUE S, SHARMA R K, et al. Effect of aggressive environment on durability of concrete containing fibrous rubber shreds and silica fume[J]. Structural Concrete, 2021, 22(5): 2611-2623.

[85] [85] SU H L, YANG J, LING T C, et al. Properties of concrete prepared with waste tyre rubber particles of uniform and varying sizes[J]. Journal of Cleaner Production, 2015, 91: 288-296.

[86] [86] YASSER N, ABDELRAHMAN A, KOHAIL M, et al. Experimental investigation of durability properties of rubberized concrete[J]. Ain Shams Engineering Journal, 2023, 14(6): 102111.

[87] [87] GUPTA T, SIDDIQUE S, SHARMA R K, et al. Behaviour of waste rubber powder and hybrid rubber concrete in aggressive environment[J]. Construction and Building Materials, 2019, 217: 283-291.

[88] [88] 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.

[89] [89] HAN Q H, WANG N, ZHANG J R, et al. Experimental and computational study on chloride ion transport and corrosion inhibition mechanism of rubber concrete[J]. Construction and Building Materials, 2021, 268: 121105.

[90] [90] SIAD H, LACHEMI M, ISMAIL M K, et al. Effect of rubber aggregate and binary mineral admixtures on long-term properties of structural engineered cementitious composites[J]. Journal of Materials in Civil Engineering, 2019, 31(11): 04019253.

[91] [91] REN F M, MO J X, WANG Q, et al. Fillers to improve the ductility and impermeability of crumb rubber concrete[J]. Construction and Building Materials, 2024, 425: 136073.

[92] [92] LI N, LONG G C, MA C, et al. Properties of self-compacting concrete (SCC) with recycled tire rubber aggregate: a comprehensive study[J]. Journal of Cleaner Production, 2019, 236: 117707.

[93] [93] KUMAR R, VERMA M, DEV N, et al. Influence of chloride and sulfate solution on the long-term durability of modified rubberized concrete[J]. Journal of Applied Polymer Science, 2022, 139(37): e52880.

[94] [94] THOMAS B S, GUPTA R C, JOHN PANICKER V. Experimental and modelling studies on high strength concrete containing waste tire rubber[J]. Sustainable Cities and Society, 2015, 19: 68-73.

[95] [95] ZHU H, LIANG J, XU J, et al. Research on anti-chloride ion penetration property of crumb rubber concrete at different ambient temperatures[J]. Construction and Building Materials, 2018, 189: 42-53.

[96] [96] ZHU R N, PANG J Y, WANG T Y, et al. Experimental research on chloride erosion resistance of rubber concrete[J]. Advances in Civil Engineering, 2020, 2020(1): 3972405.

[97] [97] COPETTI C M, BORGES P M, SQUIAVON J Z, et al. Evaluation of tire rubber surface pre-treatment and silica fume on physical-mechanical behavior and microstructural properties of concrete[J]. Journal of Cleaner Production, 2020, 256: 120670.

[98] [98] GUAN Q Y, XU Y Q, WANG J, et al. Meso-scale fracture modelling and fracture properties of rubber concrete considering initial defects[J]. Theoretical and Applied Fracture Mechanics, 2023, 125: 103834.

[99] [99] KUN L, XIN L H, BEI L B, et al. Mechanical performance and carbonation resistance of basalt fiber-polypropylene fiber rubber concrete[J]. Frontiers in Materials, 2023, 10: 1229629.

[100] [100] DONG Y J, SU C, QIAO P Z, et al. Microstructural damage evolution and its effect on fracture behavior of concrete subjected to freeze-thaw cycles[J]. International Journal of Damage Mechanics, 2018, 27(8): 1272-1288.

[101] [101] HAN X Y, DING N, CHEN A J, et al. Experimental study on freeze-thaw failure of concrete incorporating waste tire crumb rubber and analytical evaluation of frost resistance[J]. Construction and Building Materials, 2024, 439: 137356.

[102] [102] SU D Y, PANG J Y, HUANG X W. Experimental study on the influence of rubber content on chloride salt corrosion resistance performance of concrete[J]. Materials, 2021, 14(16): 4706.