[2] [2] FAN D Q, YU R, SHUI Z H, et al. A novel approach for developing a green ultra-high performance concrete (UHPC) with advanced particles packing meso-structure［J］. Construction and Building Materials, 2020, 265: 120339.

[3] [3] JIANG J Y, ZHOU W J, CHU H Y, et al. Design of eco-friendly ultra-high performance concrete with supplementary cementitious materials and coarse aggregate［J］. Journal of Wuhan University of Technology-Mater Sci Ed, 2019, 34(6): 1350-1359.

[6] [6] ASTM. ASTMC-125 standard terminology relating to concrete and concrete aggregates［S］. US: ASTM, 2007.

[7] [7] TAYLOR H F W. Cement chemistry［M］. London: Thomas Telford Publishing, 1997.

[9] [9] SHI Y, LONG G C, MA C, et al. Design and preparation of ultra-high performance concrete with low environmental impact［J］. Journal of Cleaner Production, 2019, 214: 633-643.

[14] [14] MEHTA A, SIDDIQUE R. An overview of geopolymers derived from industrial by-products［J］. Construction and Building Materials, 2016, 127: 183-198.

[22] [22] BADOGIANNIS E, KAKALI G, TSIVILIS S. Metakaolin as supplementary cementitious material［J］. Journal of Thermal Analysis and Calorimetry, 2005, 81(2): 457-462.

[24] [24] TIRONI A, TREZZA M A, SCIAN A N, et al. Kaolinitic calcined clays: factors affecting its performance as pozzolans［J］. Construction and Building Materials, 2012, 28(1): 276-281.

[29] [29] DONATELLO S, TYRER M, CHEESEMAN C R. Comparison of test methods to assess pozzolanic activity［J］. Cement and Concrete Composites, 2010, 32(2): 121-127.

[30] [30] DE LUXN M P, SORIA F. Study and critical review of the pozzolanity test［J］. Cement and Concrete Research, 1975, 5(5): 461-479.

[32] [32] MORAN W T, GILLIAND J L. Summary of methods for determining pozzolanic activity［J］. ASTM International, 1950: 109-130.

[36] [36] GUO C B, ZHAO L, YANG J L, et al. A novel perspective process for alumina extraction from coal fly ash via potassium pyrosulfate calcination activation method［J］. Journal of Cleaner Production, 2020, 271: 122703.

[46] [46] YU Q J, SAWAYAMA K, SUGITA S, et al. The reaction between rice husk ash and Ca(OH)2 solution and the nature of its product［J］. Cement and Concrete Research, 1999, 29(1): 37-43.

[47] [47] PAY J, BORRACHERO M V, MONZ J, et al. Enhanced conductivity measurement techniques for evaluation of fly ash pozzolanic activity［J］. Cement and Concrete Research, 2001, 31(1): 41-49.

[51] [51] AZEVEDO B P, SAVASTANO H, MELO N A A. Characterization and pozzolanic properties of sewage sludge ashes (SSA) by electrical conductivity［J］. Cement and Concrete Composites, 2019, 104: 103410.

[52] [52] SNELLINGS R, SCRIVENER K L. Rapid screening tests for supplementary cementitious materials: past and future［J］. Materials and Structures, 2016, 49(8): 3265-3279.

[64] [64] SHI C J, DAY R L. A calorimetric study of early hydration of alkali-slag cements［J］. Cement and Concrete Research, 1995, 25(6): 1333-1346.

[75] [75] STRAUSS U P, SMITH E H, WINEMAN P L. Polyphosphates as polyelectrolytes. I. Light scattering and viscosity of sodium polyphosphates in electrolyte solutions［J］. Journal of the American Chemical Society, 1953, 75(16): 3935-3940.

[76] [76] TAMAS F D, SARKAR A K. ROY D M. Proceedings of the conference on hydraulic cement pastes: their structure and properties［J］. Sheffield, 1976, 55.

[83] [83] WANG S D, SCRIVENER K L. 29Si and 27Al NMR study of alkali-activated slag［J］. Cement and Concrete Research, 2003, 33(5): 769-774.

[85] [85] CONG X D, KIRKPATRICK R J, YARGER J L, et al. The structure of calcium silicate hydrate: NMR and Raman spectroscopic results［M］//Nuclear Magnetic Resonance Spectroscopy of Cement-Based Materials. Berlin, Heidelberg: Springer Berlin Heidelberg, 1998: 143-158.

[92] [92] KRSTULOVIC＇ R, DABIC＇ P. A conceptual model of the cement hydration process［J］. Cement and Concrete Research, 2000, 30(5): 693-698.

[97] [97] JENNINGS H M, JOHNSON S K. Simulation of microstructure development during the hydration of a cement compound［J］. Journal of the American Ceramic Society, 1986, 69(11): 790-795.

[98] [98] BISHNOI S, SCRIVENER K L. μic: a new platform for modelling the hydration of cements［J］. Cement and Concrete Research, 2009, 39(4): 266-274.

[99] [99] VAN BREUGEL K. Numerical simulation of hydration and microstructural development in hardening cement-based materials (I) theory［J］. Cement and Concrete Research, 1995, 25(2): 319-331.

[100] [100] GARBOCZI E J, BENTZ D P. Computer simulation of the diffusivity of cement-based materials［J］. Journal of Materials Science, 1992, 27(8): 2083-2092.

[101] [101] MAEKAWA K, ISHIDA T, KISHI T. Multi-scale modeling of structural concrete[M]. England: Taylor and Francis Publish, 2008.

[102] [102] ISHIDA T, LUAN Y, SAGAWA T, et al. Modeling of early age behavior of blast furnace slag concrete based on micro-physical properties［J］. Cement and Concrete Research, 2011, 41(12): 1357-1367.