[1] JOHN V M, QUATTRONE M, ABRAO P C R A, et al. Rethinking cement standards: opportunities for a better future[J]. Cement and Concrete Research, 2019, 124: 105832.
[2] DOUGLAS HOOTON R. Future directions for design, specification, testing, and construction of durable concrete structures[J]. Cement and Concrete Research, 2019, 124: 105827.
[3] ENVIRONMENT U N, SCRIVENER K L, JOHN V M, et al. Eco-efficient cements: potential economically viable solutions for a low-CO2 cement-based materials industry[J]. Cement and Concrete Research, 2018, 114: 2-26.
[6] MA Z C, YAO Y, LIU Z C, et al. Effect of calcination and cooling conditions on mineral compositions and properties of high-magnesia and low-heat Portland cement clinker[J]. Construction and Building Materials, 2020, 260: 119907.
[9] MORSLI K, TORRE G, ZAHIR M, et al. Mineralogical phase analysis of alkali and sulfate bearing belite rich laboratory clinkers[J]. Cement and Concrete Research, 2007, 37(5): 639-646.
[13] CUESTA A, LOSILLA E R, ARANDA M A G, et al. Reactive belite stabilization mechanisms by boron-bearing dopants[J]. Cement and Concrete Research, 2012, 42(4): 598-606.
[16] KRISKOVA L, PONTIKES Y, ZHANG F, et al. Influence of mechanical and chemical activation on the hydraulic properties of gamma dicalcium silicate[J]. Cement and Concrete Research, 2014, 55: 59-68.
[20] SINYOUNG S, KUNCHARIYAKUN K, ASAVAPISIT S, et al. Synthesis of belite cement from nano-silica extracted from two rice husk ashes[J]. Journal of Environmental Management, 2017, 190: 53-60.
[21] CHEN Y L, LIN C J, KO M S, et al. Characterization of mortars from belite-rich clinkers produced from inorganic wastes[J]. Cement and Concrete Composites, 2011, 33(2): 261-266.
[22] SCRIVENER K L, JUILLAND P, MONTEIRO P J M. Advances in understanding hydration of Portland cement[J]. Cement and Concrete Research, 2015, 78: 38-56.
[23] FUJII K, KONDO W. Rate and mechanism of hydration of β-dicalcium silicate[J]. Journal of the American Ceramic Society, 1979, 62(3/4): 161-167.
[24] NICOLEAU L, NONAT A, PERREY D. The di- and tricalcium silicate dissolutions[J]. Cement and Concrete Research, 2013, 47: 14-30.
[25] ZAJAC M, SKOCEK J, LOTHENBACH B, et al. Late hydration kinetics: indications from thermodynamic analysis of pore solution data[J]. Cement and Concrete Research, 2020, 129: 105975.
[26] DURGUN E, MANZANO H, PELLENQ R, et al. Understanding and controlling the reactivity of the calcium silicate phases from first principles[J]. Chemistry of Materials, 2012, 24(7): 1262-1267.
[27] WANG Q Q, LI F, SHEN X D, et al. Relation between reactivity and electronic structure for α’L-, β- and γ-dicalcium silicate: a first-principles study[J]. Cement and Concrete Research, 2014, 57: 28-32.
[28] SHAHSAVARI R, CHEN L, TAO L. Edge dislocations in dicalcium silicates: experimental observations and atomistic analysis[J]. Cement and Concrete Research, 2016, 90: 80-88.
[29] BRAND A S, GORHAM J M, BULLARD J W. Dissolution rate spectra of β-dicalcium silicate in water of varying activity[J]. Cement and Concrete Research, 2019, 118: 69-83.
[30] TAYLOR H F W. Cement chemistry[M]. London: Thomas Telford Publishing, 1997.
[31] TERMKHAJORNKIT P, VU Q H, BARBARULO R, et al. Dependence of compressive strength on phase assemblage in cement pastes: beyond gel-space ratio-experimental evidence and micromechanical modeling[J]. Cement and Concrete Research, 2014, 56: 1-11.
[33] WANG L, DONG Y, ZHOU S H, et al. Energy saving benefit, mechanical performance, volume stabilities, hydration properties and products of low heat cement-based materials[J]. Energy and Buildings, 2018, 170: 157-169.
[34] WANG L, YANG H Q, ZHOU S H, et al. Hydration, mechanical property and C-S-H structure of early-strength low-heat cement-based materials[J]. Materials Letters, 2018, 217: 151-154.
[35] WANG L, YANG H Q, ZHOU S H, et al. Mechanical properties, long-term hydration heat, shinkage behavior and crack resistance of dam concrete designed with low heat Portland (LHP) cement and fly ash[J]. Construction and Building Materials, 2018, 187: 1073-1091.
[38] EL-DIDAMONY H, SHARARA A M, HELMY I M, et al. Hydration characteristics of β-C2S in the presence of some accelerators[J]. Cement and Concrete Research, 1996, 26(8): 1179-1187.
[39] SNCHEZ-HERRERO M J, FERNNDEZ-JIMNEZ A, PALOMO A. C3S and C2S hydration in the presence of Na2CO3 and Na2SO4[J]. Journal of the American Ceramic Society, 2017, 100(7): 3188-3198.
[40] SNCHEZ-HERRERO M J, FERNNDEZ-JIMNEZ A, PALOMO . Alkaline hydration of C2S and C3S[J]. Journal of the American Ceramic Society, 2016, 99(2): 604-611.
[42] BOH M, STANK T, ZEZULOV A, et al. Early hydration of activated belite-rich cement[J]. Advanced Materials Research, 2019, 1151: 23-27.
[44] SIDDIQUE S, NAQI A L, JANG J G. Influence of water to cement ratio on CO2 uptake capacity of belite-rich cement upon exposure to carbonation curing[J]. Cement and Concrete Composites, 2020, 111: 103616.
[45] JANG J G, LEE H K. Microstructural densification and CO2 uptake promoted by the carbonation curing of belite-rich Portland cement[J]. Cement and Concrete Research, 2016, 82: 50-57.
[46] SUI T B, FAN L, WEN Z J, et al. Properties of belite-rich Portland cement and concrete in China[J]. Journal of Civil Engineering and Architecture, 2015, 9(4): 384-392.
[49] SUI T B, FAN L, WEN Z J, et al. Study on the properties of high strength concrete using high belite cement[J]. Journal of Advanced Concrete Technology, 2004, 2(2): 201-206.
[50] YAHIA A, TANIMURA M. Rheology of belite-cement-effect of w/c and high-range water-reducer type[J]. Construction and Building Materials, 2015, 88: 169-174.
[51] GALLUCCI E, ZHANG X, SCRIVENER K L. Effect of temperature on the microstructure of calcium silicate hydrate (C-S-H)[J]. Cement and Concrete Research, 2013, 53: 185-195.
[52] NIU D T, ZHANG S H, WANG Y, et al. Effect of temperature on the strength, hydration products and microstructure of shotcrete blended with supplementary cementitious materials[J]. Construction and Building Materials, 2020, 264: 120234.
[54] SHIRANI S, CUESTA A, MORALES-CANTERO A, et al. Influence of curing temperature on belite cement hydration: a comparative study with Portland cement[J]. Cement and Concrete Research, 2021, 147: 106499.
[55] MORALES-CANTERO A, DE LA TORRE A G, CUESTA A, et al. Belite hydration at high temperature and pressure by in situ synchrotron powder diffraction[J]. Construction and Building Materials, 2020, 262: 120825.
[57] WANG L, YANG H Q, DONG Y, et al. Environmental evaluation, hydration, pore structure, volume deformation and abrasion resistance of low heat Portland (LHP) cement-based materials[J]. Journal of Cleaner Production, 2018, 203: 540-558.
[62] XIN J D, ZHANG G X, LIU Y, et al. Environmental impact and thermal cracking resistance of low heat cement (LHC) and moderate heat cement (MHC) concrete at early ages[J]. Journal of Building Engineering, 2020, 32: 101668.
[65] JIANG C M, JIANG L H, LI S X, et al. Impact of cation type and fly ash on deterioration process of high belite cement pastes exposed to sulfate attack[J]. Construction and Building Materials, 2021, 286: 122961.
[66] WANG N, CHENG X, YANG Y. Seawater corrosion resistance of low heat Portland cement concrete[J]. Materials Science Forum, 2015, 814: 207-213.
[67] HE Y J, LU L N, STRUBLE L J, et al. Effect of calcium-silicon ratio on microstructure and nanostructure of calcium silicate hydrate synthesized by reaction of fumed silica and calcium oxide at room temperature[J]. Materials and Structures, 2014, 47(1): 311-322.
[68] JIANG C M, JIANG L H, TANG X J, et al. Impact of calcium leaching on mechanical and physical behaviors of high belite cement pastes[J]. Construction and Building Materials, 2021, 286: 122983.
[72] MATSUZAWA K, SHINSUGI M, ATARASHI D, et al. Hydration reaction and hydrated products of low heat Portland cement-expansive additive-CaO·2Al2O3 system with/without CaCl2[J]. Journal of the Ceramic Society of Japan, 2018, 126(5): 389-393.
[73] SEO J, KIM S, JANG D, et al. Internal carbonation of belite-rich Portland cement: an in-depth observation at the interaction of the belite phase with sodium bicarbonate[J]. Journal of Building Engineering, 2021, 44: 102907.
[74] HAUSMANN D A. A probability model of steel corrosion in concrete[J]. Materials Performance, 1998, 37(10): 64-68.