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Lin X, Li W, Guo Y, Dong W, Castel A, et al. 2023. Biochar-cement concrete toward decarbonisation and sustainability for construction: Characteristic, performance and perspective. Journal of Cleaner Production 419:138219

Liu J, Liu G, Zhang W, Li Z, Xing F, et al. 2022. Application potential analysis of biochar as a carbon capture material in cementitious composites: a review. Construction and Building Materials 350:128715

Ashraf W. 2016. Carbonation of cement-based materials: challenges and opportunities. Construction and Building Materials 120:558−570

Jang JG, Kim GM, Kim HJ, Lee HK. 2016. Review on recent advances in CO₂ utilization and sequestration technologies in cement-based materials. Construction and Building Materials 127:762−773

Ma Z, Liao H, Wang L, Cheng F. 2021. Effects of iron/silicon/magnesium/aluminum on CaO carbonation of CO₂ in steel slag-based building materials during carbonation curing. Construction and Building Materials 298:123889

Rodriguez-Navarro C, Ilić T, Ruiz-Agudo E, Elert K. 2023. Carbonation mechanisms and kinetics of lime-based binders: an overview. Cement and Concrete Research 173:107301

Arizzi A, Parra-Fernández C. 2025. A comprehensive review of the manufacturing process and properties of natural hydraulic limes. Materials and Structures 58:152

Guzmán García Lascurain P, Rodriguez-Navarro C, Toniolo L, Goidanich S. 2025. Effects of nano- and micro-cellulose on Ca(OH)₂ formation: implications for lime-based binders. Cement and Concrete Research 192:107851

Banfill PFG, Szadurski EM, Forster AM. 2016. Deterioration of natural hydraulic lime mortars, II: effects of chemically accelerated leaching on physical and mechanical properties of carbonated materials. Construction and Building Materials 111:182−190

Bianco N, Calia A, Denotarpietro G, Negro P. 2013. Hydraulic mortar and problems related to the suitability for restoration. Periodico di Mineralogia 82:529−542

Zhang Y, Xu Z, Shao C, Qin H, Liu Z, et al. 2024. The influence of B doping on phase formation and microstructural evolution in NHL during solid-state reactions. Case Studies in Construction Materials 20:e02817

CEN-CENELEC Management Centre. 2015, Building lime - Part 1: definitions, specifications and conformity criteria, European Committee for Standardization, EN 459-1:2015 E. CEN-CENELEC Management Centre, Brussels. https://cdn.standards.iteh.ai/samples/40359/ea7f589e9a554c4c998c2c59a4f9899d/SIST-EN-459-1-2015.pdf

Morandeau A, Thiéry M, Dangla P. 2014. Investigation of the carbonation mechanism of CH and C-S-H in terms of kinetics, microstructure changes and moisture properties. Cement and Concrete Research 56:153−170

Zhang D, Zhao J, Wang D, Xu C, Zhai M, et al. 2018. Comparative study on the properties of three hydraulic lime mortar systems: natural hydraulic lime mortar, cement-aerial lime-based mortar and slag-aerial lime-based mortar. Construction and Building Materials 186:42−52

Parra-Fernández C, Arizzi A. 2025. Impact of the slaking method on the mineralogy of natural hydraulic limes and its effects on mortar mechanical properties. Cement and Concrete Research 196:107941

Barr S, McCarter WJ, Suryanto B. 2015. Bond-strength performance of hydraulic lime and natural cement mortared sandstone masonry. Construction and Building Materials 84:128−135

Silva BA, Ferreira Pinto AP, Gomes A. 2014. Influence of natural hydraulic lime content on the properties of aerial lime-based mortars. Construction and Building Materials 72:208−218

Lanas J, Pérez Bernal JL, Bello MA, Alvarez Galindo JI. 2004. Mechanical properties of natural hydraulic lime-based mortars. Cement and Concrete Research 34:2191−2201

Xu F, Yang J, Yang Y. 2016. Weather resistance of hydraulic lime used as a reinforcement material at the Helankou rock painting site. Sciences of Conservation and Archaeology 28:31−39 (in Chinese)

Sun Y. 2015. Study on the performance of hydraulic lime modified soil materials. Sciences of Conservation and Archaeology 27:27−30 (in Chinese)

Shao C, Xu Z, Liu Z, Zhang Y, Wang D. 2024. Effect of hydration degrees on the accelerated carbonization (3 % CO₂) behavior of natural hydraulic lime. Construction and Building Materials 438:137297

Liguori B, Caputo D, Iucolano F. 2015. Fiber-reinforced lime-based mortars: effect of zeolite addition. Construction and Building Materials 77:455−460

Zhang D, Zhao J, Wang D, Wang Y, Ma X, et al. 2020. Influence of pozzolanic materials on the properties of natural hydraulic lime based mortars. Construction and Building Materials 244:118360

Yang Q, Zhou H, Bartocci P, Fantozzi F, Mašek O, et al. 2021. Prospective contributions of biomass pyrolysis to China's 2050 carbon reduction and renewable energy goals. Nature Communications 12:1698

Liu L, Jiang P, Qian H, Mu L, Lu X, et al. 2022. CO₂-negative biomass conversion: an economic route with co-production of green hydrogen and highly porous carbon. Applied Energy 311:118685

Zhang J, Li G, Zhang S, Shao J, Zhang X, et al. 2025. Controlled synthesis of biochar with flower-like morphology for CO₂ adsorption: enrichment and efficient accessibility of N-containing sites. ACS Applied Materials & Interfaces 17:6742−6754

Senadheera SS, Gupta S, Kua HW, Hou D, Kim S, et al. 2023. Application of biochar in concrete – a review. Cement and Concrete Composites 143:105204

Zaid O, Alsharari F, Ahmed M. 2024. Utilization of engineered biochar as a binder in carbon negative cement-based composites: a review. Construction and Building Materials 417:135246

Jia M, Zhao Y, Wu X, Ma X. 2024. The effect of carbonation accelerator on enhancing the carbonation process and mechanical strength of air-hardening lime mortars. Construction and Building Materials 425:136067

Guo B, Lu D, Ye P, Wang K, Gao Y, et al. 2026. Effect of modified biochar on the immobilization of Pb²⁺ and CrO₄²⁻ in cement-based materials. Cement and Concrete Composites 166:106398

Ye P, Guo B, Qin H, Wang C, Liu Y, et al. 2025. Investigation of the effects of the biochar in different fractions on cement composites. Cement and Concrete Composites 162:106142

Oh D, Kitagaki R, Masuo T, Kuroda Y. 2024. Development of CO₂ absorption evaluating device for building materials. Energy Reports 11:4008−4014

Chen H, Song Z, Liu B, Sun G, Hou P, et al. 2025. Improving the carbonation resistance of supersulfated cement by nano SiO₂ and silica fume. Cement and Concrete Composites 158:105984

Nebel H, Neumann M, Mayer C, Epple M. 2008. On the structure of amorphous calcium carbonate — a detailed study by solid-state NMR spectroscopy. Inorganic Chemistry 47:7874−7879

García-Lodeiro I, Fernández-Jiménez A, Blanco MT, Palomo A. 2008. FTIR study of the sol–gel synthesis of cementitious gels: C–S–H and N–A–S–H. Journal of Sol-Gel Science and Technology 45:63−72

Ylmén R, Jäglid U. 2013. Carbonation of Portland cement studied by diffuse reflection Fourier transform infrared spectroscopy. International Journal of Concrete Structures and Materials 7:119−125

Pan X, Shi C, Farzadnia N, Hu X, Zheng J. 2019. Properties and microstructure of CO₂ surface treated cement mortars with subsequent lime-saturated water curing. Cement and Concrete Composites 99:89−99

Zhi F, Yang J, Yang G, Zhang L, Li W, et al. 2024. Investigation on the calcium leaching behaviors of cellulose ethers containing cement pastes. Cement and Concrete Composites 154:105797

Guo B, Ye P, Qin H, Wang C, Liu Y, et al. 2025. Investigation of the CO₂ adsorption behavior of alkali-modified biochar components in cement composites. Biochar X 1:e006