[1] [1] MILLER S A, HORVATH A, MONTEIRO P J M. Readily implementable techniques can cut annual CO2 emissions from the production of concrete by over 20%［J］. Environ Res Lett, 2016, 11(7): 074029.

[2] [2] HABERT G, MILLER S A, JOHN V M, et al. Environmental impacts and decarbonization strategies in the cement and concrete industries［J］. Nat Rev Earth Environ, 2020, 1(11): 559-573.

[3] [3] HUANG L Z, KRIGSVOLL G, JOHANSEN F, et al. Carbon emission of global construction sector［J］. Renew Sustain Energy Rev, 2018, 81: 1906-1916.

[4] [4] LIAO S M, WANG D, XIA C Y, et al. China’s provincial process CO2 emissions from cement production during 1993-2019［J］. Sci Data, 2022, 9(1): 165.

[5] [5] OFFICE OF LAND AND EMERGENCY MANAGEMENT. Advancing sustainable materials management: 2018 Facts Sheet［R］. Washington: The U.S. Environmental Protection Agency, 2020: 19-23.

[6] [6] EUROPEAN COMMISSION. Report on the management of construction and demolition waste in the EU［R］. ［2023-02-01］. https://environment.ec.europa.eu/topics/waste-and-recycling/construction-and-demolition-waste_en. 2011

[8] [8] LI L, XUAN D X, SOJOBI A O, et al. Efficiencies of carbonation and nano silica treatment methods in enhancing the performance of recycled aggregate concrete［J］. Constr Build Mater, 2021, 308: 125080.

[11] [11] CANTERO B, BRAVO M, DE BRITO J, et al. Mechanical behaviour of structural concrete with ground recycled concrete cement and mixed recycled aggregate［J］. J Clean Prod, 2020, 275: 122913.

[12] [12] MEHDIZADEH H, LING (BILL) T C, CHENG X F, et al. Effect of particle size and CO2 treatment of waste cement powder on properties of cement paste［J］. Can J Civ Eng, 2020, 48(3): 522-531.

[13] [13] GREVE-DIERFELD S, LOTHENBACH B, VOLLPRACHT A, et al. Understanding the carbonation of concrete with supplementary cementitious materials: a critical review by RILEM TC 281-CCC［J］. Mater Struct, 2020, 53(6): 1-34.

[15] [15] ZHAN B J, XUAN D X, ZENG W L, et al. Carbonation treatment of recycled concrete aggregate: effect on transport properties and steel corrosion of recycled aggregate concrete［J］. Cem Concr Compos, 2019, 104: 103360.

[16] [16] XUAN D X, ZHAN B J, POON C S. Assessment of mechanical properties of concrete incorporating carbonated recycled concrete aggregates［J］. Cem Concr Compos, 2016, 65: 67-74.

[17] [17] FANG X L, XUAN D X, POON C S. Empirical modelling of CO2 uptake by recycled concrete aggregates under accelerated carbonation conditions［J］. Mater Struct, 2017, 50(4): 200.

[18] [18] GHOLIZADEH-VAYGHAN A, BELLINKX A, SNELLINGS R, et al. The effects of carbonation conditions on the physical and microstructural properties of recycled concrete coarse aggregates［J］. Constr Build Mater, 2020, 257: 119486.

[19] [19] LIU S H, SHEN P L, XUAN D X, et al. A comparison of liquid-solid and gas-solid accelerated carbonation for enhancement of recycled concrete aggregate［J］. Cem Concr Compos, 2021, 118: 103988.

[20] [20] ZAJAC M, SKIBSTED J, BEN HAHA M. Effect of alkalis on enforced carbonation of cement paste: mechanism of reaction［J］. J Am Ceram Soc, 2021, 104(2): 1076-1087.

[21] [21] XUAN D X, ZHAN B J, POON C S. Durability of recycled aggregate concrete prepared with carbonated recycled concrete aggregates［J］. Cem Concr Compos, 2017, 84: 214-221.

[22] [22] LUO S R, YE S C, XIAO J Z, et al. Carbonated recycled coarse aggregate and uniaxial compressive stress-strain relation of recycled aggregate concrete［J］. Constr Build Mater, 2018, 188: 956-965.

[23] [23] LIANG C F, LU N, MA H W, et al. Carbonation behavior of recycled concrete with CO2-curing recycled aggregate under various environments［J］. J CO2 Util, 2020, 39: 101185.

[24] [24] LIANG C F, MA H W, PAN Y Q, et al. Chloride permeability and the caused steel corrosion in the concrete with carbonated recycled aggregate［J］. Constr Build Mater, 2019, 218: 506-518.

[25] [25] WU K Y, LUO S R, ZHENG J L, et al. Influence of carbonation treatment on the properties of multiple interface transition zones and recycled aggregate concrete［J］. Cem Concr Compos, 2022, 127: 104402.

[26] [26] ZHAN B J, XUAN D X, POON C S. Enhancement of recycled aggregate properties by accelerated CO2 curing coupled with limewater soaking process［J］. Cem Concr Compos, 2018, 89: 230-237.

[27] [27] FANG X L, ZHAN B J, POON C S. Enhancing the accelerated carbonation of recycled concrete aggregates by using reclaimed wastewater from concrete batching plants［J］. Constr Build Mater, 2020, 239: 117810.

[28] [28] ZHAN B J, XUAN D X, POON C S, et al. Characterization of interfacial transition zone in concrete prepared with carbonated modeled recycled concrete aggregates［J］. Cem Concr Res, 2020, 136: 106175.

[29] [29] SERENG M, DJERBI A, METALSSI O O, et al. Improvement of recycled aggregates properties by means of CO2 uptake［J］. Appl Sci, 2021, 11(14): 6571.

[30] [30] RUSSO N, LOLLINI F. Effect of carbonated recycled coarse aggregates on the mechanical and durability properties of concrete［J］. J Build Eng, 2022, 51: 104290.

[31] [31] WANG J G, ZHANG J X, CAO D D, et al. Comparison of recycled aggregate treatment methods on the performance for recycled concrete［J］. Constr Build Mater, 2020, 234: 117366.

[32] [32] XUAN D X, ZHAN B J, POON C S. Development of a new generation of eco-friendly concrete blocks by accelerated mineral carbonation［J］. J Clean Prod, 2016, 133: 1235-1241.

[33] [33] PAN C Y, SONG Y F, ZHAO Y X, et al. Performance buildup of reactive magnesia cement (RMC) formulation via using CO2-strengthened recycled concrete aggregates (RCA)［J］. J Build Eng, 2023, 65: 105779.

[34] [34] CHEN D Y, CHEN M Z, SUN Y H, et al. Sustainable use of recycled cement concrete with gradation carbonation in artificial stone: preparation and characterization［J］. Constr Build Mater, 2023, 364: 129867.

[37] [37] JIANG Y, LI L, LU J X, et al. Mechanism of carbonating recycled concrete fines in aqueous environment: the particle size effect［J］. Cem Concr Compos, 2022, 133: 104655.

[38] [38] PAN G H, ZHAN M M, FU M H, et al. Effect of CO2 curing on demolition recycled fine aggregates enhanced by calcium hydroxide pre-soaking［J］. Constr Build Mater, 2017, 154: 810-818.

[39] [39] DOS REIS G S, CAZACLIU B G, ARTONI R, et al. Effect of the accelerated carbonation treatment on the recycled sand physicochemical characteristics through the rolling carbonation process［J］. J CO2 Util, 2020, 39: 101181.

[40] [40] JIANG Y, SHEN P L, POON C S. Improving the bonding capacity of recycled concrete aggregate by creating a reactive shell with aqueous carbonation［J］. Constr Build Mater, 2022, 315: 125733.

[41] [41] YONG L, YU R, SHUI Z H, et al. Development of an environmental Ultra-High Performance Concrete (UHPC) incorporating carbonated recycled coarse aggregate［J］. Constr Build Mater, 2023, 362: 129657.

[42] [42] CHINZORIGT G, LIM M, YU M, et al. Strength, shrinkage and creep and durability aspects of concrete including CO2 treated recycled fine aggregate［J］. Cem Concr Res, 2020, 136: 106062.

[43] [43] XIAO J Z, ZHANG H H, TANG Y X, et al. Fully utilizing carbonated recycled aggregates in concrete: strength, drying shrinkage and carbon emissions analysis［J］. J Clean Prod, 2022, 377: 134520.

[44] [44] YACOUB A, DJERBI A, FEN-CHONG T. Water absorption in recycled sand: new experimental methods to estimate the water saturation degree and kinetic filling during mortar mixing［J］. Constr Build Mater, 2018, 158: 464-471.

[45] [45] FRANCO Z, KAREN S. The reaction between metakaolin and limestone and its effect in porosity refinement and mechanical properties［J］. Cem Concr Res, 2021, 140: 106307.

[46] [46] BIZZOZERO J, SCRIVENER K L. Limestone reaction in calcium aluminate cement-calcium sulfate systems［J］. Cem Concr Res, 2015, 76: 159-169.

[47] [47] MARTIN L H J, WINNEFELD F, MLLER C J, et al. Contribution of limestone to the hydration of calcium sulfoaluminate cement［J］. Cem Concr Compos, 2015, 62: 204-211.

[48] [48] ZOU S, XIAO J Z, DUAN Z H, et al. On rheology of mortar with recycled fine aggregate for 3D printing［J］. Constr Build Mater, 2021, 311: 125312.

[49] [49] BU C M, LIU L, LU X Y, et al. The durability of recycled fine aggregate concrete: a review［J］. Materials (Basel), 2022, 15(3): 1110.

[50] [50] LIU X Y, LIU L, LYU K, et al. Enhanced early hydration and mechanical properties of cement-based materials with recycled concrete powder modified by nano-silica［J］. J Build Eng, 2022, 50: 104175.

[51] [51] LI S J, GAO J M, LI Q Y, et al. Investigation of using recycled powder from the preparation of recycled aggregate as a supplementary cementitious material［J］. Constr Build Mater, 2021, 267: 120976.

[52] [52] ZAJAC M, SKIBSTED J, SKOCEK J, et al. Phase assemblage and microstructure of cement paste subjected to enforced, wet carbonation［J］. Cem Concr Res, 2020, 130: 105990.

[53] [53] LU B, SHI C J, ZHANG J K, et al. Effects of carbonated hardened cement paste powder on hydration and microstructure of Portland cement［J］. Constr Build Mater, 2018, 186: 699-708.

[54] [54] SHI Z G, LOTHENBACH B, GEIKER M R, et al. Experimental studies and thermodynamic modeling of the carbonation of Portland cement, metakaolin and limestone mortars［J］. Cem Concr Res, 2016, 88: 60-72.

[55] [55] ZAJAC M, SKIBSTED J, BULLERJAHN F, et al. Semi-dry carbonation of recycled concrete paste［J］. J CO2 Util, 2022, 63: 102111.

[57] [57] BRIKI Y, ZAJAC M, BEN HAHA M, et al. Impact of limestone fineness on cement hydration at early age［J］. Cem Concr Res, 2021, 147: 106515.

[58] [58] OUYANG X W, WANG L Q, XU S D, et al. Surface characterization of carbonated recycled concrete fines and its effect on the rheology, hydration and strength development of cement paste［J］. Cem Concr Compos, 2020, 114: 103809.

[59] [59] WU Y Q, MEHDIZADEH H, MO K H, et al. High-temperature CO2 for accelerating the carbonation of recycled concrete fines［J］. J Build Eng, 2022, 52: 104526.

[60] [60] SHEN P L, ZHANG Y Y, JIANG Y, et al. Phase assemblance evolution during wet carbonation of recycled concrete fines［J］. Cem Concr Res, 2022, 154: 106733.

[61] [61] HO H J, IIZUKA A, SHIBATA E, et al. CO2 utilization via direct aqueous carbonation of synthesized concrete fines under atmospheric pressure［J］. ACS Omega, 2020, 5(26): 15877-15890.

[62] [62] ZAJAC M, SKIBSTED J, DURDZINSKI P, et al. Kinetics of enforced carbonation of cement paste［J］. Cem Concr Res, 2020, 131: 106013.

[64] [64] ZAJAC M, SKOCEK J, DURDZINSKI P, et al. Effect of carbonated cement paste on composite cement hydration and performance［J］. Cem Concr Res, 2020, 134: 106090.

[65] [65] SHEN P L, JIANG Y, ZHANG Y Y, et al. Production of aragonite whiskers by carbonation of fine recycled concrete wastes: an alternative pathway for efficient CO2 sequestration［J］. Renew Sustain Energy Rev, 2023, 173: 113079.

[66] [66] SHEN P L, LU J X, ZHANG Y Y, et al. Preparation aragonite whisker-rich materials by wet carbonation of cement: towards yielding micro-fiber reinforced cement and sequestrating CO2［J］. Cem Concr Res, 2022, 159: 106891.

[67] [67] MEHDIZADEH H, MO K H, LING T C. CO2-fixing and recovery of high-purity vaterite CaCO3 from recycled concrete fines［J］. Resour Conserv Recycl, 2023, 188: 106695.

[68] [68] SHEN P L, SUN Y J, LIU S H, et al. Synthesis of amorphous nano-silica from recycled concrete fines by two-step wet carbonation［J］. Cem Concr Res, 2021, 147: 106526.

[69] [69] FANG X L, XUAN D X, ZHAN B J, et al. A novel upcycling technique of recycled cement paste powder by a two-step carbonation process［J］. J Clean Prod, 2021, 290: 125192.

[70] [70] ZHU C H, FANG Y H, WEI H. Carbonation-cementation of recycled hardened cement paste powder［J］. Constr Build Mater, 2018, 192: 224-232.

[71] [71] FANG Y F, CHANG J. Microstructure changes of waste hydrated cement paste induced by accelerated carbonation［J］. Constr Build Mater, 2015, 76: 360-365.

[73] [73] ZHANG Y H, CHEN H P, WANG Q. Accelerated carbonation of regenerated cementitious materials from waste concrete for CO2 sequestration［J］. J Build Eng, 2022, 55: 104701.

[74] [74] ZHANG N, ZHANG D, ZUO J, et al. Potential for CO2 mitigation and economic benefits from accelerated carbonation of construction and demolition waste［J］. Renew Sustain Energy Rev, 2022, 169: 112920.

[75] [75] TORRENTI J M, AMIRI O, BARNES DAVIN L, et al. The FastCarb Project: taking advantage of the accelerated carbonation of recycled concrete aggregates［J］. Case Stud Constr Mater, 2022, 17(5): e01349.

[76] [76] LOTHENBACH B, SCRIVENER K, HOOTON R D. Supplementary cementitious materials［J］. Cem Concr Res, 2011, 41(12): 1244-1256.

[77] [77] LU B, SHI C J, CAO Z J, et al. Effect of carbonated coarse recycled concrete aggregate on the properties and microstructure of recycled concrete［J］. J Clean Prod, 2019, 233: 421-428.

[78] [78] FANG X L, ZHAN B J, POON C S. Enhancement of recycled aggregates and concrete by combined treatment of spraying Ca2+ rich wastewater and flow-through carbonation［J］. Constr Build Mater, 2021, 277: 122202.

[79] [79] LI L F, JIANG Y, PAN S Y, et al. Comparative life cycle assessment to maximize CO2 sequestration of steel slag products［J］. Constr Build Mater, 2021, 298: 123876.