[1] [1] O’CONNOR J, NGUYEN T B T, HONEYANDS T, et al. Production, characterisation, utilisation, and beneficial soil application of steel slag: a review［J］. Journal of Hazardous Materials, 2021, 419: 126478.

[7] [7] YANG B M, LAI W L, CHANG Y M, et al. Using desulfurization slag as the aquacultural amendment for fish pond water quality improvement: mechanisms and effectiveness studies［J］. Journal of Cleaner Production, 2017, 143: 1313-1326.

[8] [8] KUO W T. Properties of compressed concrete paving units made produced using desulfurization slag［J］. Environmental Progress & Sustainable Energy, 2015, 34(5): 1365-1371.

[10] [10] MASTALI M, SHAAD K M, ABDOLLAHNEJAD Z, et al. Towards sustainable bricks made with fiber-reinforced alkali-activated desulfurization slag mortars incorporating carbonated basic oxygen furnace aggregates［J］. Construction and Building Materials, 2020, 232: 117258.

[11] [11] CHO B, CHOI H. Physical and chemical properties of concrete using GGBFS-KR slag-gypsum binder［J］. Construction and Building Materials, 2016, 123: 436-443.

[12] [12] LEE B, KIM G, NAM J, et al. Compressive strength, resistance to chloride-ion penetration and freezing/thawing of slag-replaced concrete and cementless slag concrete containing desulfurization slag activator［J］. Construction and Building Materials, 2016, 128: 341-348.

[13] [13] KUO W T, WANG H Y, SHU C Y. Engineering properties of cementless concrete produced from GGBFS and recycled desulfurization slag［J］. Construction and Building Materials, 2014, 63: 189-196.

[14] [14] KUO W T, HOU T C. Engineering properties of alkali-activated binders by use of desulfurization slag and GGBFS［J］. Construction and Building Materials, 2014, 66: 229-234.

[15] [15] CHEN Y L, KO M S, CHANG J E, et al. Recycling of desulfurization slag for the production of autoclaved aerated concrete［J］. Construction and Building Materials, 2018, 158: 132-140.

[17] [17] MILLER S A, JOHN V M, PACCA S A, et al. Carbon dioxide reduction potential in the global cement industry by 2050［J］. Cement and Concrete Research, 2018, 114: 115-124.

[18] [18] LIU Y, KUANG Y Q, HUANG N S, et al. CO2 emission from cement manufacturing and its driving forces in China［J］. International Journal of Environment and Pollution, 2009, 37(4): 369.

[19] [19] SHI C J. Characteristics and cementitious properties of ladle slag fines from steel production［J］. Cement and Concrete Research, 2002, 32(3): 459-462.

[20] [20] JIA Z J, CHEN C, SHI J J, et al. The microstructural change of C-S-H at elevated temperature in Portland cement/GGBFS blended system［J］. Cement and Concrete Research, 2019, 123: 105773.

[21] [21] LI Y Y, NI W, GAO W, et al. Corrosion evaluation of steel slag based on a leaching solution test［J］. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects, 2019, 41(7): 790-801.

[23] [23] EL-DIDAMONY H, AMER A A, EL-SOKKARY T M, et al. Effect of substitution of granulated slag by air-cooled slag on the properties of alkali activated slag［J］. Ceramics International, 2013, 39(1): 171-181.

[25] [25] ADESANYA E, OHENOJA K, DI MARIA A, et al. Alternative alkali-activator from steel-making waste for one-part alkali-activated slag［J］. Journal of Cleaner Production, 2020, 274: 123020.

[26] [26] SHI C J. Steel slag: its production, processing, characteristics, and cementitious properties［J］.Journal materials in civil engineering, 2004, 16(3): 230-236.