Analyzing the impact of fiber-reinforced recycled ceramic waste concrete on carbon emissions and mechanical performance: a systematic review

Yuzheng Geng; Yongcheng Ji; Dayang Wang; Yinghan Yuan; Hecheng Zhang

doi:10.1007/s44242-025-00081-x

Low-carbon Materials and Green Construction ›› 2025, Vol. 3 ›› Issue (1) :26 DOI: 10.1007/s44242-025-00081-x

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Analyzing the impact of fiber-reinforced recycled ceramic waste concrete on carbon emissions and mechanical performance: a systematic review

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Abstract

This study systematically reviews the utilization of fiber-reinforced recycled ceramic waste concrete, focusing on its mechanical performance and environmental benefits. Ceramic waste replaced coarse and fine aggregates and cementitious materials in concrete mixtures. The results demonstrate that replacing 20% of coarse and 50% of fine aggregates with ceramic waste significantly enhances compressive strength, reaching 32.98 MPa and 35.83 MPa, respectively. Moreover, these replacements reduced carbon emissions during concrete production by 6–250 kg CO₂e/t, depending on the application. Introducing reinforcing fibers, such as carbon and Polyvinyl Alcohol (PVA) fibers, further improved concrete’s crack resistance, frost durability, and toughness under extreme conditions. These findings validate the feasibility of using ceramic waste as a sustainable alternative in construction materials, contributing to performance optimization and carbon reduction. The research offers new insights into eco-friendly concrete development aligned with the sustainable development goals (SDGs).

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Ceramic wastes / Aggregates / Admixtures / Reinforcing fibers / Compressive strength / Carbon reduction

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Yuzheng Geng, Yongcheng Ji, Dayang Wang, Yinghan Yuan, Hecheng Zhang. Analyzing the impact of fiber-reinforced recycled ceramic waste concrete on carbon emissions and mechanical performance: a systematic review. Low-carbon Materials and Green Construction, 2025, 3(1): 26 DOI:10.1007/s44242-025-00081-x

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Mehta, P. K., & Meryman H. (2009). Tools for reducing carbon emissions due to cement consumption. Structure, 1(1): 11.

[2]	Lin, S. (2018). Analysis of the research status quo of the comprehensive utilization of ceramic waste resourcefulness. Foshan Ceramics, 28(07): 4–6+16.

[3]	Oikonomou ND. Recycled concrete aggregates. Cement and Concrete Composites, 2005, 27(2): 315-318.

[4]	Communication from the Commission to the European Parliament, the Council, the European Economic and Social Committee and the Committee of the Regions. Roadmap to a Resource Efficient Europe. (2011). http://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX:52011DC0571

[5]	Torgal, F.P., & Jalali, S. (2011). Construction and Demolition (C&D) Wastes. In: Eco-efficient Construction and Building Materials. Springer, London. https://doi.org/10.1007/978-0-85729-892-8_4

[6]	Mefteh H, Kebaïli O, Oucief H, Berredjem L, Arabi N. Influence of moisture conditioning of recycled aggregates on the properties of fresh and hardened concrete. J. Cleaner Prod., 2013, 54: 282-288.

[7]	Behera M, Bhattacharyya SK, Minocha AK, Deoliya R, Maiti S. "Recycled aggregate from C&D waste & its use in concrete -A breakthrough towards sustainability in the construction sector: A review. "Constr. Build. Mater., 2014, 68: 501-516.

[8]	Hongwen, M., & Jing, Y. (1997). Principles and Methods for the Design of Ceramic Materials in the SiO₂-Al₂O₃-MgO-CaO-Na₂O-K₂O System. In Proceedings of the 9th National Phase Diagram Academic Conference (pp. 21-24). School of Materials Science and Engineering, China University of Geosciences.

[9]	Torkittikul P, Chaipanich A. Utilization of ceramic waste as fine aggregate within Portland cement and fly ash concretes. Cement and Concrete Composites, 2010, 32(6): 440-449.

[10]	Omary S, Ghorbel E, Wardeh G. Relationships between recycled concrete aggregates characteristics and recycled aggregates concretes properties. Construction And Building Materials, 2016, 108: 163-174.

[11]	Xuan D, Zhan B, Poon CS. Assessment of mechanical properties of concrete incorporating carbonated recycled concrete aggregates. Cement and Concrete Composites, 2016, 65: 67-74.

[12]	Li T, Xiao J, Zhu C, Zhong Z. Experimental study on mechanical behaviors of concrete with large-size recycled coarse aggregate. Construction and Building Materials, 2016, 120: 321-328.

[13]	Rashid K, Razzaq A, Ahmad M, Rashid T, Tariq S. Experimental and analytical selection of sustainable recycled concrete with ceramic waste aggregate. construction and Building Materials, 2017, 154: 829-840.

[14]	Gayarre FL, González JS, Viñuela RB, Pérez CL-C, Serrano López MA. Use of recycled mixed aggregates in floor blocks manufacturing. Journal Of Cleaner Production, 2017, 167: 713-722.

[15]	Bui NK, Satomi T, Takahashi H. Improvement of mechanical properties of recycled aggregate concrete basing on a new combination method between recycled aggregate and natural aggregate. Construction and Building Materials, 2017, 148: 376-385.

[16]	Señas L, Priano C, Marfil S. Influence of recycled aggregates on properties of self-consolidating concretes. Construction and Building Materials, 2016, 113: 498-505.

[17]	De Brito, J., Pereira, A. S., & Correia, J. R. (2005). Mechanical behaviour of non-structural concrete made with recycled ceramic aggregates. Cement and Concrete Composites, 27(4), 429–433. https://doi.org/10.1016/j.cemconcomp.2004.07.005

[18]	Gomes M, De Brito J. Structural concrete with incorporation of coarse recycled concrete and ceramic aggregates: Durability performance. Materials and Structures, 2009, 42(5): 663-675.

[19]	Debieb F, Kenai S. The use of coarse and fine crushed bricks as aggregate in concrete. Construction and Building Materials, 2008, 22(5): 886-893.

[20]	Senthamarai RM, Devadas MP. Concrete with waste aggregate. Cement and Concrete Composites, 2005, 27(9–10): 910-913.

[21]	cheng Y, huang F, liu J. Experimental study on the strength of concrete with waste ceramic aggregate. Highway, 2012, 11: 75-78

[22]	Lavat, A. E., Trezza, M. A., & Poggi, M. (2009). Characterization of ceramic roof tile wastes as pozzolanic admixture. Waste Management, 29(5), 1666–1674. https://doi.org/10.1016/j.wasman.2008.10.019

[23]	Naceri, A., & Hamina, M. C. (2009). Use of waste brick as a partial replacement of cement in mortar. Waste Management, 29(8), 2378–2384. https://doi.org/10.1016/j.wasman.2009.03.026

[24]	Li, L., Liu, W., You, Q., Chen, M., Zeng, Q. (2020). Waste ceramic powder as a pozzolanic supplementary filler of cement for developing sustainable building materials. Journal of Cleaner Production, 259 Journal of Cleaner Production, 259 , 120853.

[25]	Ay N, Unal M. The use of ceramic tile in cement production. Cement and Concrete Research, 2000, 30: 497-499.

[26]	Puertas F, Garcia-Diaz I, Barba A, Gazulla M, Palacios M, Gomez M, Martinez-Ramirez S. Ceramic wastes as alternative raw materials for Portland cement clinker production. Cement and Concrete Composites, 2008, 30: 798-805.

[27]	Turner LK, Collins FG. Carbon dioxide equivalent (CO2-e) emissions: A comparison between geopolymer and OPC cement concrete. Construction and Building Materials, 2013, 43: 125-130.

[28]	Li, Z. (2019). Experimental study on the basic mechanical properties of fiber toughened waste ceramic aggregate concrete. Xinyang Normal College, MA thesis.

[29]	Kryeziu D, Selmani F, Mujaj A, Kondi I. Recycled concrete aggregates: A promising and sustainable option for the construction industry. Journal of Human, Earth, and Future, 2023

[30]	Awolusi TF, Ekhasomhi AI, Aluko OG, Akinkurolere OO, Azab M, Deifalla AF. Performance evaluation of fiber-reinforced ferroconcrete using response surface methodology. Civil Engineering Journal (Iran), 2023, 9(4): 939-959.

[31]	Jasim AMDA, Wong LS, Kong SY, Al-Zand AW, Midhin MAK. An evaluative review of recycled waste material utilization in high-performance concrete. Civil Engineering Journal (Iran), 2023, 9(11): 2927-2957.

[32]	Hashim AA, Anaee R, Nasr MS. Improving the mechanical, corrosion resistance, microstructural and environmental performance of recycled aggregate concrete using ceramic waste powder as an alternative to cement. Ceramics, 2025, 8(1): 11.

[33]	Ahmad J, Sabri MM, Majdi A, Alattyih W, Khan I, Alam M. Durability and microstructure aspects of sustainable concrete made with ceramic waste: A review. Frontiers in Materials, 2025

[34]	Tokareva A, Waldmann D. Durability of cement mortars containing fine demolition wastes as supplementary cementitious materials. Construction and Building Materials, 2025, 477141316

[35]	Dai X, Shen A, He Z, Zuo X, Guo Y, Li Z. Advanced compound treatment strategies for brick-concrete recycled aggregates: Focusing on volcanic ash slurry and innovative chemical solution. Construction and Building Materials, 2025, 479141252

[36]	Anand P, Sinha AK, Rajhans P, Bhowmik PN. Enhancing concrete sustainability: Synergistic effects of individual and dual treatments on recycled coarse aggregate from construction and demolition waste. Journal of Structural Design and Construction Practice, 2025

[37]	Wang C, Zhao X, Zhao J, Zhao Y. Synergistic application of weathered granite and recycled coarse aggregate in concrete: Mechanical properties and microstructural mechanisms. Construction and Building Materials, 2025, 482141695

[38]	Lawanwadeekul S, Bunma M, Kattiyawara K, Sillapapiromsuk S, Phonphuak N. Upcycling ceramic industrial and local plastic waste into alternative construction materials focusing on performance and material utilization. Journal of Cleaner Production, 2025, 501145337

[39]	Tahwia AM, Abdellatief M, Salah A, Youssf O. Valorization of recycled concrete powder, clay brick powder, and volcanic pumice powder in sustainable geopolymer concrete. Scientific Reports, 2025

[40]	Barbhuiya S, Kanavaris F, Ashish DK, Tu W, Das BB, Adak D. Ground waste glass as a supplementary cementitious material for concrete: Sustainable utilization, material performance and environmental considerations. Journal of Sustainable Cement-Based Materials, 2025

[41]	Chen J, Duan J, Zhu Q, Jin W, Lu C, Lv M, Li W, Li Y, Lv Y. High temperature resistance of slag/fly ash-based geopolymer concrete with fully recycled coarse aggregate. Construction and Building Materials, 2025, 482141587

[42]	Yuan H, Zhu L, Wang X. Long-term performance of steel fiber reinforced recycled concrete: Creep calculation model based on recycled aggregate attached mortar and the interfacial transition zone of steel fiber. Construction and Building Materials, 2025, 474141163

[43]	Antunes A, Costa H, do Carmo R, Júlio E. A comprehensive review of sustainable use of construction and demolition waste as recycled aggregates in the production of concrete – Properties, mix design and on-site applications. Construction and Building Materials, 2025, 482141733

[44]	Vieira T, Alves A, de Brito J, Correia JR, Silva RV. Durability-related performance of concrete containingfine recycled aggregates from crushed bricks and sanitary ware. Materials and Design, 2016, 90: 767-776.

[45]	Singh, A., & Srivastava, V. (2018). Ceramic waste in concrete—A review. Recent Advances on Engineering, Technology and Computational Sciences (RAETCS), 1-6.

[46]	Alves AV, Vieira TF, de Brito J, Correia JR. Mechanical properties of structural concrete with fine recycled ceramic aggregates. Construction and Building Materials, 2014, 64: 103-113.

[47]	medina, C., Juan, A., Frias, M., Sanchez de Rojas, M. I., Moran, J. M., & Guerra, M. I. (2011). Caracterizacion de los hormigones realizados con aridos reciclados procedentes de la industria de ceramica sanitaria. materiales de Construccion, 61 (304), 533–546. https://doi.org/10.3989/mc.2011.59710

[48]	Suzuki M, Seddik Meddah M, Sato R. Use of porous ceramic waste aggregates for internal curing of high-performance concrete. Cement and Concrete Research, 2009, 39(5): 373-381.

[49]	ogawa Y, Bui PT, Kawai K, Sato R. Effects of porous ceramic roof tile waste aggregate on strength development and carbonation resistance of steam-cured fly ash concrete. construction and Building Materials, 2020

[50]	Muragishi, Y., Ogawa, Y., Kawai K., & Sato, R. (2014). Effect of porous ceramic waste aggregate on durability of steam cured fly ash concrete (in Japanese), Cem. Sci. Concr. Technol. 68, 337–344. https://doi.org/10.14250/cement.68.337

[51]	Bui, P. T , Ogawa, Y., Doi, N., Kawai, K., & Sato, R. (2015). Properties of steam-cured fly ash concrete using porous ceramic waste aggregate. In: 13th International Conference on Recent Advances in Concrete Technology and Sustainability Issues, Ottawa, 303, 323–336.

[52]

Bui, P.T., Muragishi, Y., Ogawa, Y., Kawai, K., & Sato, R. (2015). Effects of porous ceramic waste aggregate as an internal curing agent on steam-cured high strength fly ash concrete. In Proceedings of the international conference on sustainable structural concrete, La Plata, Argentina (pp. 66–76).

[53]	Medina, C., Sánchez De Rojas, M. I., & Frías, M. (2013). Properties of recycled ceramic aggregate concretes: water resistance. Cem Concr Compos, 40: 21–29. https://doi.org/10.1016/j.cemconcomp.2013.04.005

[54]	Higashiyama, H., Yagishita, F., Sano, M., & Takahashi, O. (2012). Compressive strength and resistance to chloride penetration of mortars using ceramic waste as fine aggregate. Constr Build Mater, 26. https://doi.org/10.1016/j.conbuildmat.2011.05.008

[55]	Polish Committee for Standardization. (2001). Methods of reducing laboratory samples (PN-EN 932-2:2001). Polish Committee for Standardization.

[56]	Polish Committee for Standardization. (2007). Tests of thermal properties and resistance of aggregates to weather conditions, part 1: determination of frost resistance (PN-EN 1367-1:2007). Polish Committee for Standardization.

[57]	Klimek B, Szulej J, Ogrodnik P. The effect of replacing sand with aggregate from sanitary ceramic waste on the durability of stucco mortars. Clean Technologies and Environmental Policy, 2020, 22(9): 1929-1941.

[58]	Medina C, Frías M, De Rojas MS. Microstructure and properties of recycled concretes using ceramic sanitary ware industry waste as coarse aggregate. Construction And Building Materials, 2012, 31: 112-118.

[59]	Medina C, De Rojas MS, Frías M. Reuse of sanitary ceramic wastes as coarse aggregate in eco-efficient concretes. Cement and Concrete Composites, 2012, 34(1): 48-54.

[60]	de Brito J, Pereira AS, Correia JR. Mechanical behaviour of non-structural concrete made with recycled ceramic aggregates. Cement and Concrete Composites, 2005, 27(4): 429-433.

[61]	Suzuki M, Seddik Meddah M, Sato R. Use of porous ceramic waste aggregates for internal curing of high-performance concrete. Cement and Concrete Research, 2009

[62]	Suzuki M, Seddik Meddah M, Sato R. Use of porous ceramic waste aggregates for internal curing of high-performance concrete. Cement and Concrete Research, 2009, 39: 373-381.

[63]	Bui PT, Ogawa Y, Nakarai K, Kawai K, Sato R. Internal curing of class-F flyash concrete using high-volume roof-tile waste aggregate. Materials and Structures, 2017, 50: 203.

[64]	Monteiro, P. (2006). Concrete: Microstructure, Properties, and Materials. McGraw-Hill Publishing.

[65]	Ueda, T., Shrestha, J., Rashid, K., & Zhang, D. (2016). Moisture and temperature effects on interface mechanical properties for external bonding. International Conference on Durability of Concrete Structures. 1. https://docs.lib.purdue.edu/icdcs/2016/KEYNOTE/1

[66]	Rashid K, Zhang D, Ueda T, Jin W. Investigation on concrete-PCM interface under elevated temperature: At material level and member level. Construction and Building Materials, 2016, 125: 465-478.

[67]	Rashid K, Ueda T, Zhang D, Miyaguchi K, Nakai H. Experimental and analytical investigations on the behavior of interface between concrete and polymer cement mortar under hygrothermal conditions. Construction and Building Materials, 2015, 94: 414-425.

[68]	Ji Y, Wang D. Durability of recycled aggregate concrete in cold regions. Case Studies in Construction Materials, 2022, 17e01475

[69]	Evangelista, L., & de Brito, J. (2007). Mechanical behaviour of concrete made with fine recycled concrete aggregates. Cement and Concrete Composites, 29 (5), 397–401. https://doi.org/10.1016/j.cemconcomp.2006.12.004

[70]	Tang WC, Lo Y, Nadeem A. Mechanical and drying shrinkage properties of structural-graded polystyrene aggregate concrete. Cement and Concrete Composites, 2008, 30(5): 403-409.

[71]	Taha B, Nounu G. Properties of concrete contain mixed colour waste recycled glass as sand and cement replacement. Construction and Building Materials, 2008, 22(5): 713-720.

[72]	Bektas F, Wang K, Ceylan H. Effects of crushed clay brick aggregate on mortar durability. Construction and Building Materials, 2009, 23(5): 1909-1914.

[73]	Westerholm M, Lagerblad B, Silfwerbrand J, Forssberg E. Influence of fine aggregate characteristics on the rheological properties of mortars. Cement and Concrete Composites, 2008, 30(4): 274-282.

[74]	Özkan, Ö., & Yüksel, İ. (2008). Studies on mortars containing waste bottle glass and industrial by-products. Construction and Building Materials, 22(6), 1288–1298. https://doi.org/10.1016/j.conbuildmat.2007.01.015

[75]	Neville, A. M. (2011). Properties of Concrete. Harlow Pearson Education.

[76]	Taha B, Nounu G. Properties of concrete contains mixed color waste recycled glass as sand and cement replacement. Construction and Building Materials, 2008, 22(5): 713-720.

[77]	Siddique, S., Shrivastava, S., & Chaudhary, S. (2017). Lateral force microscopic examination of the interfacial transition zone in ceramic concrete. Constr Build Mater, 155: 688–725. https://doi.org/10.1016/j.conbuildmat.2017.08.080

[78]	Mohammadhosseini, H., & Yatim, J. M. (2017). Microstructure and residual properties of green concrete composites incorporating waste carpet fibers and palm oil fuel ash at elevated temperatures. J Clean Prod, 144: 8–21.

[79]	Medina, C., Sánchez de Rojas, M. I., & Frías, M. (2012). Reuse of sanitary ceramic wastes as coarse aggregate in eco-efficient concretes. Cement Concr Compos, 34: 48–54. https://doi.org/10.1016/j.cemconcomp.2011.08.015

[80]	Medina, C., Frías, M., Sánchez de Rojas, M. I., Thomas, C., & Polanco, J. A. (2012b). Gas permeability in concrete containing recycled ceramic sanitary ware aggregate. Constr Build Mater, 37: 597–605. https://doi.org/10.1016/j.conbuildmat.2012.08.023

[81]	Matias, G., Faria, P., & Torres, I. (2014). Lime mortars with heat treated clays and ceramicwaste: a review. Constr Build Mater, 73: 125–136. https://doi.org/10.1016/j.conbuildmat.2014.09.028

[82]	Stratoura M., Iaz D. R., Badogiannis E. (2018). Chloride penetration in lightweight aggregate mortars incorporating supplementary cementing materials. AdvCiv Eng, 97: 159–167. https://doi.org/10.1155/2018/9759167

[83]	Jeronimo, V. L., Meira, G. R., Pinto da Silva Filho, L. C. (2018). Performance of self-compacting concretes with wastes from heavy ceramic industry against corrosion by chlorides. construction and building Materials, 169, 900–910. https://doi.org/10.1016/j.conbuildmat.2018.03.034.

[84]

Fang, V., Chen, M. C., Yang, C. et al. (2018). Experimental study on the carbonation properties of concrete mixed with ceramic powder. In Proceedings of the 27th National Conference on Structural Engineering (Vol. II, pp. 559-562). National-Local Joint Engineering Research Center for Operation and Maintenance Safety and Assurance Technology of Rail Transit Infrastructure, East China Jiaotong University; School of Civil Engineering and Architecture, East China Jiaotong University

[85]	Yang S., Wang G. X., Lu S. N., Zhu M. Q. & Qu F. (2018). Study on the effect of acid rain-load combined action on the neutralization of recycled ceramic concrete. Bulletin of the Silicate Industry, 37(12), 3977–3982. http://gsytb.jtxb.cn/CN/Y2018/V37/I12/3977

[86]	Aziza K, Li B, Huang B, Kholjigit K, Yu Y. Mitigating autogenic shrinkage in high-performance concrete using wollastonite: A structural enhancement approach. Structural Concrete, 2024

[87]	Cao H, Xu Z, Peng X. An improved fick model for predicting carbonation depth of concrete. Coatings, 2024, 14(11): 1345.

[88]	Mohamed AM, Tayeh BA, Majeed SS, Aisheh YIA, Salih MNA. Fresh, hardened, durability and microstructure properties of seawater concrete: A systematic review. Journal of CO2 Utilization, 2024, 83102815

[89]	Zhao, F. Z., Wen, B. L. & Liu, R. J. (2019). Research progress on ceramic powder as a mineral admixture in concrete. Concrete and Cement Products, 8, 22–26. https://doi.org/10.19761/j.1000-4637.2019.08.022.05

[90]	Shukor, A., Hossein Mohammadhosseini, Tahir, M. M., Samadi, M., & Rahman, A. (2018). Microstructure and Strength Properties of Mortar Containing Waste Ceramic Nanoparticles. Arabian Journal for Science and Engineering, 43(10), 5305–5313. https://doi.org/10.1007/s13369-018-3154-x

[91]	Ding Y, Dong H, Cao M. Study on the activity of volcanic ash in ceramic waste powder. Journal of Building Materials, 2015, 18(5): 867-872

[92]	Zhang, Z. J., Wang, G. X., Zhong, M. F. & Su, D. G. (2009). Reaction characteristics of ceramic polishing waste-lime system. Journal of Building Materials, 12(6), 661–666.

[93]	Kannan, D. M., Aboubakr, S. H., EL-Dieb, A. S., & Reda Taha, M. M. (2017). High performance concrete incorporating ceramic waste powder as large partial replacement of Portland cement. Construction and Building Materials, 144, 35–41. https://doi.org/10.1016/j.conbuildmat.2017.03.115

[94]	steiner lr, bernardin am, pelisser f. Effectiveness of ceramic tile polishing residues as supplementary cementitious materials for cement mortars. sustainable materials and technologies, 2015, 4: 30-35.

[95]	El-Dieb, A. S., Taha, M. R., Kanaan, D., & Aly, S. T. (2018). Ceramic waste powder: from landfill to sustainable concretes. Proceedings of the Institution of Civil Engineers - Construction Materials, 171(3), 109–116. https://doi.org/10.1680/jcoma.17.00019

[96]	Yunhong C, Fei H, Guanglu Li, et al. . Experimental study on the compatibility of ceramic concrete mixes. Highway, 2013, 9: 209-212

[97]	Cheng, Y., Huang, F., Liu, R., Hou, J., & Li, G. (2015). Test research on effects of waste ceramic polishing powder on the permeability resistance of concrete. Materials and Structures, 49(3), 729–738. https://doi.org/10.1617/s11527-015-0533-6

[98]	Kan W, Yang Z, Yu L. Study on frost resistance of the carbon-fiber-reinforced concrete. Applied Sciences, 2022

[99]	Zhong, J., Shi, J., Shen, J., Zhou, G., & Wang, Z. (2019). Investigation on the failure behavior of engineered cementitious composites under freeze-thaw cycle. materials, 12(11). https://doi.org/10.3390/ma12111808

[100]

Jiang Z, Jin S, Xu W. Durability investigation of fiber-reinforced functionally graded concretes in cold regions. Applied Sciences, 2022

[101]

Parr, W. C., & Taguchi, G. (1989). Introduction to Quality Engineering: Designing Quality into Products and Processes. Technometrics, 31(2), 255–255. https://doi.org/10.2307/1268824

[102]

Maghsoodloo S, Ozdemir G, Jordan V, Huang CH. Strengths and limitations of Taguchi's contributions to quality, manufacturing, and process engineering. Journal Of Manufacturing Systems, 2004, 23: 73-126.

[103]

Olivia, M., & Nikraz, H. (2012). Properties of fly ash geopolymer concrete designed by Taguchi method. Materials & Design (1980-2015), 36, 191–198. https://doi.org/10.1016/j.matdes.2011.10.036

[104]

ramezanianpour AA, Kazemian A, Radaei E, AzariJafari H, Moghaddam MA. Influence of Iranian low-reactivity GGBFS on the properties of mortars and concretes by Taguchi method. Computers and Concrete, 2014, 13(4): 423-436.

[105]

Cao, Q., Gao, Q., Gao, R., & Jia, J. (2018). Chloride penetration resistance and frost resistance of fiber reinforced expansive self-consolidating concrete. Construction and Building Materials, 158, 719–727. https://doi.org/10.1016/j.conbuildmat.2017.10.029

[106]

Kang S-T, Kim J-K. Investigation on the flexural behavior of UHPCC considering the effect of fiber orientation distribution. Construction and Building Materials, 2012, 28: 57-65.

[107]

Au, C., & Buyukozturk, O. (2005). Effect of Fiber Orientation and Ply Mix on Fiber Reinforced Polymer-Confined Concrete. Journal of Composites for Construction, 9(5), 397–407. https://doi.org/10.1061/(asce)1090-0268(2005)9:5(397)

[108]

Vincent T, Ozbakkaloglu T. Influence of fiber orientation and specimen end condition on axial compressive behavior of FRP-confined concrete. Construction And Building Materials, 2013, 47: 814-826.

[109]

Zaid, O., Mukhtar, F. M., M-García, R., El Sherbiny, M. G., & Mohamed, A. M. (2022). Characteristics of high-performance steel fiber reinforced recycled aggregate concrete utilizing mineral filler. Case Studies in Construction Materials, 16, e00939. https://doi.org/10.1016/j.cscm.2022.e00939

[110]

Powers, T. C. (1962). Physical properties of cement paste. Proceedings of the fourth international conference on the chemistry of cement, Washington, DC, 43(2), 577-613. US National Bureau of Standards Monograph.

[111]

Powers TC. A working hypothesis for further studies of frost resistance of concrete. J. Am. Concr. Inst., 1945, 16: 245-272

[112]

Powers TC, Brownyard TL. Studies of the physical properties of hardened Portland cement paste. J. Am. Con. Inst., 1947, 18: 549-602

[113]

Sun W. Durability Evaluation and Service Life Prediction of Modern Concrete, 2015China Architecture & BuildingPress(In Chinese)

[114]

Fagerlund G. Frost destruction of concrete-a study of the validity of different mechanisms. Nordic Concrete Research, 2018, 58: 35-54.

[115]

Zhijie W, Ziqi W, Ganping Z, Ruijin S. Early crack resistance of composite fiber concrete. Railway Engineering, 2020, 60: 145-149

[116]

Yang Z, He R, Tan Y, Chen H, Cao D. Air pore structure, strength and frost resistance of air-entrained mortar with different dosages of nano-SiO2 hydrosol. Construction and Building Materials, 2021, 308125096

[117]

Ogrodnik, P., & Szulej, J. (2018). The assessment of possibility of using sanitary ceramic waste as concrete aggregate—determination of the basic material characteristics. Applied Sciences, 8(7), 1205. https://doi.org/10.3390/app8071205

[118]

Deng Z, Lin J, Li N. A review on recycling seashells as aggregates and binders for mortar and concrete in China: Production, engineering properties and new applications. Sustainable Materials and Technologies, 2025, 43e01242

[119]

Announcement of the Ministry of Housing and Urban-Rural Development on the Publication of the National Standard for Calculating Carbon Emissions from Buildings. (n.d.). www.mohurd.gov.cn. Retrieved April 29, 2024, from https://www.mohurd.gov.cn/gongkai/zhengce/zhengcefilelib/201905/20190530240723.html

[120]

Deng Z, Yang Z, Pan X. Synergetic effects of recycled crumb rubber and glass cullet on the engineering properties of geopolymer mortar. Cement and Concrete Composites, 2023, 137104907

[121]

Deng Z, Yang Z, Bian J, Pan X, Wu G, Guo F, Fu R, Yan H, Deng Z, Chen S. Engineering properties of PVA fibre-reinforced geopolymer mortar containing waste oyster shells. Materials, 2022, 15(19): 7013.

[122]

Deng Z, Zhang S, Deng Z. PVA fiber-reinforced geopolymer mortar made with hybrid recycled aggregates: Toward thermal insulation, lightweight and improved durability. Journal Of Cleaner Production, 2023, 426: 139200-139200.