U.N. Environment, Emissions Gap Report 2022, UNEP - UN Environment Programme (2022). http://www.unep.org/resources/emissions-gap-report-2022 (accessed August 23, 2023).

YildirimIZ, PrezziM. Chemical, Mineralogical, and Morphological Properties of Steel Slag. Advances in Civil Engineering, 2011, 2011: e463638

PeysA, IsteriV, YliniemiJ, YorkshireAS, LemougnaPN, UttonC, ProvisJL, SnellingsR, HaneinT. Sustainable iron-rich cements: Raw material sources and binder types. Cement and Concrete Research, 2022, 157: 106834

Euroslag. EuroSlag Statistics 2021, Euroslag (n.d.). https://www.euroslag.com/products/statistics/statistics-2021/ (accessed September 25, 2023).

GuoJ, BaoY, WangM. Steel slag in China: Treatment, recycling, and management. Waste Management, 2018, 78: 318-330

Elakneswaran, Y., Noguchi N., Matumoto K., Morinaga Y., Chabayashi T., Kato H., & Nawa T. Characteristics of Ferrite-Rich Portland Cement: Comparison With Ordinary Portland Cement, Frontiers in Materials 6 (2019). https://www.frontiersin.org/articles/https://doi.org/10.3389/fmats.2019.00097 (accessed September 25, 2023).

GartnerE, MyersD. Influence of Tertiary Alkanolamines on Portland Cement Hydration. Journal of the American Ceramic Society, 1993, 76: 1521-1530

Atmaca A., & Atmaca N. (2016). Determination of correlation between specific energy consumption and vibration of a raw mill in cement industry. Anadolu University Journal of Science and Technology-A Applied Sciences and Engineering, 17(1). https://doi.org/10.18038/btda.11251

G.G. Mejeoumov, Improved cement quality and grinding efficiency by means of closed mill circuit modeling - ProQuest, (n.d.). https://www.proquest.com/openview/95eb16488835e1ddb48934989b0a74dc/1?cbl=18750&pq-origsite=gscholar&parentSessionId=CnfKsRLiP4j8tsKGnUe%2FDbOzscOEo%2BsyPpQOfV%2BARGs%3D (accessed September 25, 2023).

ShaoY, LuX, LiQ, DongY, ZhangL, JiangC, DuP, ChengX. Study on the preparation and sulfate resistance of Portland cement clinker with the high Fe/Al ratio of ferrite phase. Cement and Concrete Composites, 2022, 134: 104699

YangHM, ZhangSM, WangL, ChenP, ShaoDK, TangSW, LiJZ. High-ferrite Portland cement with slag: Hydration, microstructure, and resistance to sulfate attack at elevated temperature. Cement and Concrete Composites, 2022, 130: 104560

ZhangG, WuZ, ChengX, SunX, ZhangC, ZhouM. Mechanical properties of high-ferrite oil-well cement used in shale gas horizontal wells under various loads. Construction and Building Materials, 2022, 319: 126067

Fan B., Huang K., Yang X., Wu Z., Ni X., & Cheng X. (2022). Study on mineral composition design and mechanical properties improvement mechanism of high ferrite oil well cement. Frontiers in Materials, 9. https://doi.org/10.3389/fmats.2022.1003776

AdolfssonD, MenadN, VigghE, BjörkmanB. Steelmaking slags as raw material for sulphoaluminate belite cement. Advances in Cement Research, 2007, 19: 147-156

ŽibretL, ŠterK, BorštnarM, LoncnarM, DolenecS. The Incorporation of Steel Slag into Belite-Sulfoaluminate Cement Clinkers. Applied Sciences, 2021, 11: 1840

IacobescuRI, PontikesY, KoumpouriD, AngelopoulosGN. Synthesis, characterization and properties of calcium ferroaluminate belite cements produced with electric arc furnace steel slag as raw material. Cement and Concrete Composites, 2013, 44: 1-8

TsakiridisPE, PapadimitriouGD, TsivilisS, KoroneosC. Utilization of steel slag for Portland cement clinker production. Journal of Hazardous Materials, 2008, 152: 805-811

GaoT, DaiT, ShenL, JiangL. Benefits of using steel slag in cement clinker production for environmental conservation and economic revenue generation. Journal of Cleaner Production, 2021, 282: 124538

DunantCF, JosephS, PrajapatiR, AllwoodJM. Electric recycling of Portland cement at scale. Nature, 2024, 629: 1055-1061

Baral A., Isteri V., Adesanya E., Yliniemi J., Fabritius T., & Hanein T. Early-Age Hydration of an EAF Slag Based Alite–Ferrite Cement Clinker in the Presence of Na₂CO_3. In A. Jędrzejewska, F. Kanavaris, M. Azenha, F. Benboudjema, D. Schlicke (Eds.), International RILEM Conference on Synergising Expertise Towards Sustainability and Robustness of Cement-Based Materials and Concrete Structures (pp. 485–495). Springer Nature Switzerland. https://doi.org/10.1007/978-3-031-33187-9_45

ScrivenerKL, JohnVM, GartnerEM. Eco-efficient cements: Potential, economically viable solutions for a low CO2, cement based materials industry, UN Environment Program, 2016 UNEP)

Hanifa M., Agarwal R., Sharma U., Thapliyal P. C., & Singh L. P. (2023). A review on CO₂ capture and sequestration in the construction industry: Emerging approaches and commercialised technologies. Journal of CO ₂ Utilization, 67, 102292. https://doi.org/10.1016/j.jcou.2022.102292

HuR, XieJ, WuS, YangC, YangD. Study of Toxicity Assessment of Heavy Metals from Steel Slag and Its Asphalt Mixture. Materials (Basel), 2020, 13: 2768

Code for design of industrial waste composition in cement kiln GB 50634–2010, (2010). https://www.chinesestandard.net/PDF/English.aspx/GB50634-2010 (accessed May 17, 2024).

SFS-EN 12457–2, Characterisation of waste. Leaching. Compliance test for leaching of granular waste materials and sludges. One stage batch test at a liquid to solid ratio of 10 l/kg for materials with particle size below 4 mm (without or with size reduction), (2002).

SFS-EN 196–10:EN, Methods of testing cement. Part 10: Determination of the water-soluble chromium (VI) content of cement, (n.d.). https://online.sfs.fi/fi/index/tuotteet/SFS/CEN/ID2/1/412849.html.stx (accessed December 13, 2023).

DilnesaBZ, WielandE, LothenbachB, DähnR, ScrivenerKL. Fe-containing phases in hydrated cements. Cement and Concrete Research, 2014, 58: 45-55

MummeWG. Crystal structure of tricalcium silicate from a Portland cement clinker and its application to quantitative XRD analysis. Neues Jahrbuch Für Mineralogie - Monatshefte, 1995, 1995: 146-160

Mumme W.G., Hill R.J., Bushnell-wye G., Segnit E.R., Rietveld crystal structure refinements, crystal chemistry and calculated powder diffraction data for the polymorphs of dicalcium silicate and related phases, in: 1995. https://api.semanticscholar.org/CorpusID:135973945

RedhammerGJ, TippeltG, RothG, AmthauerG. Structural variations in the brownmillerite series Ca2(Fe2−xAlx)O5: Single-crystal X-ray diffraction at 25 °C and high-temperature X-ray powder diffraction (25 °C ≤ T ≤ 1000 °C). American Mineralogist, 2004, 89: 405-420

SFS-EN 197–1:, Cement. Part 1: Composition, specifications and conformity criteria for common cements, (n.d.). https://online.sfs.fi/fi/index/tuotteet/SFS/CEN/ID2/1/180815.html.stx (accessed March 25, 2024).

T. H.F.W, 1 Portland cement and its major constituent phases, in: Cement Chemistry, Thomas Telford Publishing, 1997: pp. 1–28. https://doi.org/10.1680/cc.25929.0001

IchikawaM, IkedaS, KomukaiY. Effect of cooling rate and Na2O content on the character of the interstitial materials in portland cement clinker. Cement and Concrete Research, 1994, 24: 1092-1096

Gartner E.M., Young J.F., Damidot D.A., & Jawed I. (2002). Hydration of Portland cement. In Bensted J., & Barnes P.(Eds), Structure and Performance of Cements. Taylor & Francis. https://www.google.com/books?hl=fi&lr=&id=6wPpkyrWE5oC&oi=fnd&pg=PA57&dq=gartner+Hydration+of+Portland+Cement&ots=5bCdfkcjGd&sig=T1B_ZNpCktVUbzGZkyAS2S8yb94

TaylorHFW. Cement Chemistry, 1997 2 Thomas Telford

NoguchiN, SiventhirarajahK, ChabayashiT, KatoH, NawaT, ElakneswaranY. Hydration of ferrite-rich Portland cement: Evaluation of Fe-hydrates and Fe uptake in calcium-silicate-hydrates. Construction and Building Materials, 2021, 288: 123142

ShahV, ScrivenerK, BhattacharjeeB, BishnoiS. Changes in microstructure characteristics of cement paste on carbonation. Cement and Concrete Research, 2018, 109: 184-197

YuH, TangC, MehdizadehH, GuoM-Z, LingT-C. Effects of early hydration of alite and belite phases on subsequent accelerated carbonation. Construction and Building Materials, 2024, 411: 134675

Teune, I. E., Schollbach, K., Florea, M. V. A., & Brouwers, H. J. H. (2023). Carbonation of hydrated cement: The impact of carbonation conditions on CO₂ sequestration, phase formation, and reactivity. Journal of Building Engineering, 79, 107785. https://doi.org/10.1016/j.jobe.2023.107785

Martínez-RamírezS, Fernández-CarrascoL. Carbonation of ternary cement systems. Construction and Building Materials, 2012, 27: 313-318

PhungQT, FrederickxL, NguyenTN, NguyenVT. Resistance of ordinary and low-carbon cements to carbonation: Microstructural and mineralogical alteration. Cement and Concrete Composites, 2023, 143: 105260

CuestaA, De la TorreÁG, SantacruzI, DiazA, TrtikP, HollerM, LothenbachB, ArandaMAG. Quantitative disentanglement of nanocrystalline phases in cement pastes by synchrotron ptychographic X-ray tomography. IUCrJ, 2019, 6: 473-491

S. Karen, S. Ruben, L. Barbara, A Practical Guide to Microstructural Analysis of Cementitious Materials, CRC Press, 2016. https://www.routledge.com/A-Practical-Guide-to-Microstructural-Analysis-of-Cementitious-Materials/Scrivener-Snellings-Lothenbach/p/book/9781138747234 (accessed November 18, 2023).

Collier N. C. (2016). Transition and decomposition temperatures of cement phases – A collection of thermal analysis data. Ceramics - Silikaty, 60(4), 1–10. https://doi.org/10.13168/cs.2016.0050

Auroy, M., Poyet, S., Le Bescop, P., Torrenti, J.-M., Charpentier, T., Moskura, M., & Bourbon, X. (2018). Comparison between natural and accelerated carbonation (3% CO₂): Impact on mineralogy, microstructure, water retention and cracking. Cement and Concrete Research, 109, 64–80. https://doi.org/10.1016/j.cemconres.2018.04.012

VillainG, ThieryM, PlatretG. Measurement methods of carbonation profiles in concrete: Thermogravimetry, chemical analysis and gammadensimetry. Cement and Concrete Research, 2007, 37: 1182-1192

Zajac M., Skibsted J., Durdzinski P., Bullerjahn F., Skocek J., & Ben Haha M. (2020). Kinetics of enforced carbonation of cement paste. Cement and Concrete Research, 131(20), 106013. https://doi.org/10.1016/j.cemconres.2020.106013

2003/33/EC: Council Decision of 19 December 2002 establishing criteria and procedures for the acceptance of waste at landfills pursuant to Article 16 of and Annex II to Directive 1999/31/EC, https://Webarchive.Nationalarchives.Gov.Uk/Eu-Exit/Https://Eur-Lex.Europa.Eu/Legal-Content/EN/TXT/?uri=CELEX:32003D0033 (n.d.). https://www.legislation.gov.uk/eur/2003/33/annex/division/2 (accessed December 14, 2023).

AlbaN, VázquezE, GassóS, BaldasanoJM. Stabilization/solidification of MSW incineration residues from facilities with different air pollution control systems. Durability of matrices versus carbonation, Waste Management, 2001, 21: 313-323

ZhouQ, GlasserFP. Kinetics and mechanism of the carbonation of ettringite. Advances in Cement Research, 2000, 12: 131-136

ChenB, HorgniesM, HuetB, MorinV, JohannesK, KuznikF. Comparative kinetics study on carbonation of ettringite and meta-ettringite based materials. Cement and Concrete Research, 2020, 137: 106209

NishikawaT, SuzukiK, ItoS, SatoK, TakebeT. Decomposition of synthesized ettringite by carbonation. Cement and Concrete Research, 1992, 22: 6-14

SanchezF, GervaisC, GarrabrantsAC, BarnaR, KossonDS. Leaching of inorganic contaminants from cement-based waste materials as a result of carbonation during intermittent wetting. Waste Management, 2002, 22: 249-260

Kropp T.A.B.J., Hilsdorf H.K. (1989). Formation of Silica gel During Carbonation of Cementitious Systems Containing Slag Cements. In Malhotra V.M. (Eds.), Proceedings of the 3rd International Conference on Fly Ash, Silica Fume, Slag, and Natural Pozzoeans in Concrete (pp. 1413-1428). Trondheim, Norway. https://doi.org/10.14359/1817

ŠavijaB, LukovićM. Carbonation of cement paste: Understanding, challenges, and opportunities. Construction and Building Materials, 2016, 117: 285-301

ManciniA, WielandE, GengG, DähnR, SkibstedJ, WehrliB, LothenbachB. Fe(III) uptake by calcium silicate hydrates. Applied Geochemistry, 2020, 113: 104460

LothenbachB, KulikDA, MatscheiT, BalonisM, BaquerizoL, DilnesaB, MironGD, MyersRJ. Cemdata18: A chemical thermodynamic database for hydrated Portland cements and alkali-activated materials. Cement and Concrete Research, 2019, 115: 472-506

SunF, PangX, WeiJ, ZengJ, NiuJ. Synthesis of alite, belite and ferrite in both monophase and polyphase states and their hydration behavior. Journal of Materials Research and Technology, 2023, 25: 3901-3916

Okoronkwo, M. U., & Glasser, F. P. (2016). Compatibility of hydrogarnet, Ca₃Al₂(SiO₄)x(OH)₄(3–x), with sulfate and carbonate-bearing cement phases: 5–85 °C. Cement and Concrete Research, 83, 86–96. https://doi.org/10.1016/j.cemconres.2016.01.013

LangeLC, HillsCD, PooleAB. Preliminary Investigation into the Effects of Carbonation on Cement-Solidified Hazardous Wastes. Environmental Science and Technology, 1996, 30: 25-30