References
- Yoo D.Y., Banthia N., You I., Lee S.J., Recent advances in cementless ultra-high-performance concrete using alkali-activated materials and industrial byproducts: A review, Cem. Concr. Compos., 2024, 148: 105470
- Tamta S., Chaudhury R., Sharma U., Hanifa M., Thapliyal P.C., Singh L.P., Low lime – low carbon cement: Achieving sustainability through reduction of CO2 emissions and utilizing limestone mining rejects, Constr. Build. Mater., 2025, 470: 140476
- Aghaee K., Carbon capture, utilization, and storage for sustainable construction: Insights into CO2 mixing, curing, and mineralization, Carbon Capture Sci. Technol., 2025, 17: 100503
- Kanagaraj B., Lubloy E., Anand N., Hlavick V., Kiran T., Investigation of physical, chemical, mechanical, and microstructural properties of cement-less concrete – state-of-the-art review, Constr. Build. Mater., 2023, 365: 130020
- Xiao R., Huang B., Zhou H., Ma Y., Jiang X., A state-of-the-art review of crushed urban waste glass used in OPC and AAMs (geopolymer): Progress and challenges, Clean. Mater., 2022, 4: 100083
- Kong Y.K., Kurumisawa K., Fresh properties and characteristic testing methods for alkali-activated materials: A review, J. Build. Eng., 2023, 75: 106830
- Ponomar V., Luukkonen T., Yliniemi J., Revisiting alkali-activated and sodium silicate-based materials in the early works of Glukhovsky, Constr. Build. Mater., 2023, 398: 132474
- Ahmad M.R., Das C.S., Khan M., Dai J.G., Development of low-carbon alkali-activated materials solely activated by flue gas residues (FGR) waste from incineration plants, J. Clean. Prod., 2023, 397: 136597
- Bajpai R., Choudhary K., Srivastava A., Sangwan K.S., Singh M., Environmental impact assessment of fly ash and silica fume based geopolymer concrete, J. Clean. Prod., 2020, 254: 120147
- Yoo D.Y., Banthia N., You I., Lee S.J., Recent advances in cementless ultra-high-performance concrete using alkali-activated materials and industrial byproducts: A review, Cem. Concr. Compos., 2024, 148: 105470
- Fiala L., Lin W.T., Hotěk P., Cheng A., Feasibility study of developing cementless blended materials as 3D printable materials, Case Stud. Constr. Mater., 2023, 19: e02675
- Song H., Kim D., Yoon S., Yum W.S., Jeon D., Oh J.E., Development of artificial leak-free phase change material (PCM) aggregates using emulsion technique, cementless binder, and cold-bonded palletization, Constr. Build. Mater., 2024, 411: 134293
- Do T.M., Kang G.O., Kim Y.S., Development of a new cementless binder for controlled low strength material (CLSM) using entirely by-products, Constr. Build. Mater.,2019, 206: 576–589
- Al-Noaimat Y.A., Chougan M., Al-kheetan M.J., Al-Mandhari O., Al-Saidi W., Al-Maqbali M., et al., 3D printing of limestone-calcined clay cement: A review of its potential implementation in the construction industry, Results Eng., 2023, 18: 101115
- Nassrullah G., Ali M.M., Al-Rub R.K.A., Cho C.S., El-Khasawneh B., Ghaffar S.H., et al., Optimizing cement-based material formulation for 3D printing: Integrating carbon nanotubes and silica fume, Case Stud. Constr. Mater., 2025, 22: e04579
- Wu M., Wang Z., Chen Y., Zhu M., Yu Q., Effect of steel slag on rheological and mechanical properties of sulfoaluminate cement-based sustainable 3D printing concrete, J. Build. Eng., 2024, 98: 111345
- Cho E., Gwon S., Cha S., Shin M., Impact of accelerator on rheological properties of cement composites with cellulose microfibers: 3D printing perspective, J. Build. Eng., 2025, 101: 112538
- Girskas G., Kligys M., 3D concrete printing review: equipment, materials, mix design, and properties, Buildings, 2025, 15: 2049
- Abedi M., Waris M.B., Al-Alawi M.K., Al-Jabri K.S., Al-Saidy A.H., From local earth to modern structures: A critical review of 3D printed cement composites for sustainable and efficient construction, J. Build. Eng., 2025, 100: 111638
- Rahemipoor S., Hasany M., Mehrali M., Almdal K., Ranjbar N., Mehrali M., Phase change materials incorporation into 3D printed geopolymer cement: A sustainable approach to enhance the comfort and energy efficiency of buildings, J. Clean. Prod., 2023, 417: 138005
- de Moraes M.J.B., Nagata E.Y., Duran A.J.F.P., Rossignolo J.A., Alkali activated materials applied in 3D printing construction: A review, Heliyon, 2024, 10: e26696
- Zaid O., Ouni M.H.E., Advancements in 3D printing of cementitious materials: A review of mineral additives, properties, and systematic developments, Constr. Build. Mater., 2024, 427: 136254
- Suryanto B., Higgins J., Aitken M.W., Tambusay A., Suprobo P., Developments in Portland cement/GGBS binders for 3D printing applications: Material calibration and structural testing, Constr. Build. Mater., 2023, 407: 133561
- Lu B., Zhu W., Weng Y., Liu Z., Yang E.H., Leong K.F., et al., Study of MgO-activated slag as a cementless material for sustainable spray-based 3D printing, J. Clean. Prod., 2020, 258: 120671
- T. Crook, M. Li, R. Buswell, D. Allinson, Anisotropic hygrothermal properties of 3D printed concrete, In Abstracts of the 3rd International Conference on Moisture in Buildings 2025, 23–24 Oct 2025. UCL Open Environment, UCL Press, Portugal; 2025. pp. 1–3
- Tamimi A.A., Hassan H., Rodriguez-Ubinas E., Alhaidary H., Mansouri A., Thermal performance of 3D concrete printed walls: calculated and in-situ measured U-values, J. Asian Archit. Build. Eng., 2023, 23: 1903–1915
- Kaszynka M., Olczyk N., Techman M., Skibicki S., Zielinski A., Filipowicz K., et al., Thermal-humidity parameters of 3D printed wall, IOP Conf. Ser. Mater. Sci. Eng., 2019, 471: 082018
- Cai J., Wang J.S., Zhang Q., Du C., Meloni M., Feng J., State-of-the-art of mechanical properties of 3D printed concrete, Case Stud. Constr. Mater., 2024, 21: e03847
- Lin W.T., Korniejenko K., Hebda M., Łach M., Mikuła J., Engineering properties of ternary cementless blended material, Int. J. Eng. Technol. Innov., 2020, 10: 191–199
- Wu Y.H., Huang R., Tsai C.J., Lin W.T., Utilizing residues of CFB co-combustion of coal, sludge and TDF as an alkali activator in eco-binder, Constr. Build. Mater., 2015, 80: 69–75
- Lin W.T., Development of cementless binder for low thermal conductivity materials: Reactive ultra-fine fly ash mixed with co-fired fly ash, Case Stud. Constr. Mater., 2022, 16: e00899
- Lin W.T., Mierzwiński D., Hebda M., Sprince A., Mucsi G., Feasibility of 3D printing on environmentally friendly cementless materials with low thermal conductivity, Int. J. Eng. Technol. Innov., 2025, 15: 182–194
- Chen Y., Çopuroğlu O., Rodriguez C.R., Filho F.F.M., Schlangen E., Characterization of air-void systems in 3D printed cementitious materials using optical image scanning and X-ray computed tomography, Mater. Charact., 2021, 173: 110948
- Babafemi A.J., Kolawole J.T., Miah M.J., Paul S.C., Panda B.A., Concise review on interlayer bond strength in 3D concrete printing, Sustainability, 2021, 13: 7137
- ASTM C191, Standard test methods for time of setting of hydraulic cement by Vicat needle. ASTM International, West Conshohocken, PA; 2021
- ASTM C1437, Standard test method for flow of hydraulic cement mortar. ASTM International, West Conshohocken, PA; 2020
- ASTM C143, Standard test method for slump of hydraulic-cement concrete. ASTM International, West Conshohocken, PA; 2020
- ASTM C109, Standard test method for compressive strength of hydraulic cement mortars (using 2-in. or [50-mm] cube specimens). ASTM International, West Conshohocken, PA; 2020
- Wang X., Lv J., Yang J., Zhu J., He B., Wang X., et al., Synergistic effects of ground granulated blast furnace slag and circulating fluidized bed fly ash in lime-activated cementitious materials, Case Stud. Constr. Mater., 2025, 22: e04259
- Liu W., Liu X., Zhang L., Wan Y., Li H., Jiao X., Rheology, mechanics, microstructure and durability of low-carbon cementitious materials based on circulating fluidized bed fly ash: A comprehensive review, Constr. Build. Mater., 2024, 411: 134688
- Zhao J., Liu Q., Long B., Cheng Z., Wang H., Wang D., Utilization of coal gangue power generation industry by-product CFA in cement: Workability, rheological behavior and microstructure of blended cement paste, Fuel, 2023, 345: 128185
- Coffetti D., Candamano S., Crea F., Coppola L., On the role of alkali content on one-part alkali activated slag pastes produced with tri- blend solid activators, Constr. Build. Mater., 2023, 409: 133868
- Zhang B., Ma Z., Yan J., Zhang Y., Wang Y., Effects of fly ash vitrified slag (FVS) dosage and alkali content on the reaction of alkali-activated material (AAM), Mater. Today Commun., 2025, 46: 112507
- Liu J., Guo L., Xi Y., Cheng L., Chen D., Study on the rheology, mechanical properties and microstructure of polypropylene fibers in different binder systems, J. Build. Eng., 2024, 90: 109491
- Prateek G., Zheng K., Gong C., Wei S., Zhou X., Yuan Q., Preparing high strength binder materials with high proportion of steel slag through reverse filling approach, Constr. Build. Mater., 2023, 368: 130474
- Alnahhal M.F., Kim T., Kim J.H., Hajimohammadi A., Yielding mechanisms and structuration of sodium silicate-activated fly ash and slag pastes: Origins of critical strains, Constr. Build. Mater., 2025, 489: 142213
- Kaya E., Ciza B., Yalçınkaya Ç., Felekoğlu B., Yazıcı H., Çopuroğlu O., A comparative study on the effectiveness of fly ash and blast furnace slag as partial cement substitution in 3D printable concrete, J. Build. Eng., 2025, 108: 112841
- Kang S.H., Kang H., Lee N., Kwon Y.H., Moon J., Development of cementless ultra-high performance fly ash composite (UHPFC) using nucleated pozzolanic reaction of low Ca fly ash, Cem. Concr. Compos., 2022, 132: 104650
- He P., Zhang X., Chen H., Zhang Y., Waste-to-resource strategies for the use of circulating fluidized bed fly ash in construction materials: A mini review, Powder Technol., 2021, 393: 773–785
- Luan J., Chen X., Ning Y., Shi Z., Beneficial utilization of ultra-fine dredged sand from Yangtze River channel as a concrete material based on the minimum paste theory, Case Stud. Constr. Mater., 2022, 16: e01098
- Huo Y., Huang J., Lu D., Sun H., Liu T., Wang J., et al., Retarding the setting time of alkali-activated slag paste by processing the alkali activator into pills and capsules, Structures, 2024, 64: 106644
- Abudawaba F., Gomaa E., Gheni A.A., Feys D., ElGawady M.A., Evaluation of fresh properties of high calcium content fly ash-based alkali-activated 3D-printed mortar, J. Build. Eng., 2025, 104: 112244
- Rahman M., Rawat S., Yang R., Mahil A., Zhang Y.X., A comprehensive review on fresh and rheological properties of 3D printable cementitious composites, J. Build. Eng., 2024, 91: 109719
- Ali N., Soliman A.M., Influence of viscosity modifier addition methods on the rheological behaviour of alkali-activated slag systems, Constr. Build. Mater., 2025, 483: 141714
- Swathi B., Vidjeapriya R., Stimulation of calcium (Sodium)-alumina-silicate-hydrate (C(N)-A-S-H) gel by nano-alumina in the cleaner production of agro-based alkali-activated concrete, Sustainable Chem. Pharm., 2025, 46: 102100
- Ahi O., Ertunç Ö., Bundur Z.B., Bebek Ö., Automated flow rate control of extrusion for 3D concrete printing incorporating rheological parameters, Autom. Constr., 2024, 160: 105319
- Kanagasuntharam S., Ramakrishnan S., Sanjayan J., Encapsulation of sodium silicate to attain on demand buildability enhancement in concrete 3D printing, J. Build. Eng., 2024, 94: 109912
- Chen Y., Cheikh K.E., Rahier H., Methodology for the design and optimization of potassium silicate-activated slag used as the binder of 3D printable materials, Constr. Build. Mater., 2025, 490: 142536
- Feys D., How much is bulk concrete sheared during pumping?, Constr. Build. Mater., 2019, 223: 341–351
- Xiao J., Han N., Zhang L., Zou S., Mechanical and microstructural evolution of 3D printed concrete with polyethylene fiber and recycled sand at elevated temperatures, Constr. Build. Mater., 2021, 293: 123524
- Bassan de Moraes M.J., Nagata E.Y., Felício Peres Duran A.J., Rossignolo J.A., Alkali activated materials applied in 3D printing construction: A review, Heliyon, 2024, 10: e26696
- Liu J., Hu L., Tang L., Zhang E.Q., Ren J., Shrinkage behaviour, early hydration and hardened properties of sodium silicate activated slag incorporated with gypsum and cement, Constr. Build. Mater., 2020, 248: 118687
- Zhang W., Liu X., Zhang Z., Li Y., Gu J., Synergic effects of circulating fluidized bed fly ash-red mud-blast furnace slag in green cementitious materials: hydration products and environmental performance, J. Build. Eng., 2022, 58: 105007
- Guo W., Yao W., Liang G., Shi C., She A., Wei Y., Mechanical properties, microstructure and life-cycle assessment of eco-friendly cementitious materials containing circulating fluidized bed fly ash and ground granulated blast furnace slag, J. Build. Eng., 2024, 95: 110293
- Liu C., Li Z., Nie S., Skibsted J., Ye G., Structural evolution of calcium sodium aluminosilicate hydrate (C-(N-)A-S-H) gels induced by water exposure: The impact of Na leaching, Cem. Concr. Res., 2024, 178: 107432
- Lyu B.C., Guo L.P., Wu J.D., Fei X.P., Bian R.S., The impacts of calcium acetate on reaction process, mechanical strength and microstructure of ordinary Portland cement paste and alkali-activated cementitious paste, Constr. Build. Mater., 2022, 359: 129492
- Guan X., Shi J., Protection of galvanized steel using benzotriazole as a corrosion inhibitor in simulated concrete pore solution and alkali-activated fly ash solution, Cem. Concr. Compos., 2023, 136: 104880
- Fu Q., Bu M., Zhang Z., Xu W., Yuan Q., Niu D., Hydration characteristics and microstructure of alkali-activated slag concrete: a review, Engineering, 2023, 20: 162–179
- Shahbaz M., Behfarnia K., Thermal strength of the alkali-activated slag concrete, AUT J. Civil Eng., 2020, 4: 303–314
- D. Niall, R. West, O. Kinnane, S. McCormack, Influence of ground granulated blastfurnace slag on the thermal properties of PCM-concrete composite panels. Advanced Building Skins Conference 2016, Bern, Switzerland; 10 to 11 October, 2016, pp. 963–973
- Lin W.T., Reactive ultra-fine fly ash as an additive for cement-based materials, Mater. Today Commun., 2020, 25: 101466
- Chuang P.M., Yeih W.C., Huang R., Chang J.J., A study on reactive ultra-fine fly ash and sulfoaluminate cement in self-leveling mortar, Appl. Sci., 2025, 15: 1358
- Han F., Zhu Z., Zhang H., Li Y., Fu T., Effect of steel slag on the properties of alkali-activated slag material: a comparative study with fly ash, Materials, 2024, 17: 2495
- Ramires M.L.V., de Castro C.A.N., Nagasaka Y., Nagashima A., Assael M.J., Wakeham W.A., Standard reference data for the thermal conductivity of water, J. Phys. Chem. Ref. Data, 1995, 24: 1377–1381
- Kadoya K., Matsunaga N., Nagashima A., Viscosity and thermal conductivity of dry air in the gaseous phase, J. Phys. Chem. Ref. Data, 1985, 14: 947–970
- Dai J., Wang Q., Bi R., Wang C., Han Z., Du W., et al., Research on influencing factors and time-varying model of thermal conductivity of concrete at early age, Constr. Build. Mater., 2022, 315: 125638
- Daza-Badilla L., Gómez R., Díaz-Noriega R., Avudaiappan S., Skrzypkowski K., Saavedra-Flores E.I., et al., Thermal conductivity in concrete samples with natural and synthetic fibers, Materials, 2024, 17: 817
- Li K., Lu J.X., Chen Z., Ali H.A., Ban J., Poon C.S., A novel self-hardening cementitious material by the self-activation of glass powder, Constr. Build. Mater., 2024, 411: 134559
- Fang G., Zhang M., Multiscale micromechanical analysis of alkali-activated fly ash-slag paste, Cem. Concr. Res., 2020, 135: 106141
- Park J., Bui Q., Lee J., Joh C., Yang I., Interlayer strength of 3d-printed mortar reinforced by postinstalled reinforcement, Materials, 2021, 14: 6630
- Sapata A., Šinka M., Šahmenko G., Bensa L.K., Hanžič L., Šter K., et al., Establishing benchmark properties for 3D-printed concrete: a study of printability, strength, and durability, J. Compos. Sci., 2025, 9: 74
- Maroszek M., Hager I., Mróz K., Sitarz M., Hebda M., Anisotropy of mechanical properties of 3D-printed materials – influence of application time of subsequent layers, Materials, 2025, 18: 3845
- Cao Y., Shen L., Mukherjee A., Abbas A., Dias-da-Costa D., Improvement of the interlayer bonding strength in a 3D-printed mortar with biocement sprayed into interlayer surfaces, Virtual Phys. Prototyp., 2025, 20: e2521104
- Chen K., Liu Q., Chen B., Zhang S., Ferrara L., Li W., Effect of raw materials on the performance of 3D printing geopolymer: A review, J. Build. Eng., 2024, 84: 108501
- Liu B., Xie Y., Zhou S., Yuan Q., Influence of ultrafine fly ash composite on the fluidity and compressive strength of concrete, Cem. Concr. Res., 2000, 30: 1489–1493
- Ye H., Cartwright C., Rajabipour F., Radlińska A., Understanding the drying shrinkage performance of alkali-activated slag mortars, Cem. Concr. Compos., 2017, 76: 13–24
- Babafemi A.J., Kolawole J.T., Miah M.J., Paul S.C., Panda B.A., Concise review on interlayer bond strength in 3D concrete printing, Sustainability, 2021, 13: 7137
- Tseng K.C., Chi M., Yeih W., Huang R., Influence of slag/fly ash as partial cement replacement on printability and mechanical properties of 3D-printed concrete, Appl. Sci., 2025, 15: 3933
- Mierzwiński D., Łach M., Gądek S., Lin W.T., Tran D.H., Korniejenko K., A brief overview of the use of additive manufacturing of concrete materials in construction, Acta Innov., 2023, 48: 22–37