[1] Z. Zhao*, S. Remond, D. Damidot, W. Xu (2015). Influence of fine recycled concrete aggregates on the properties of mortars. Construction and Building Materials, 81, 179-186.

[2] Z. Zhao*, M. Benzerzour, N. E Abriak, D. Damidot. L. Courard, D. Wang (2018). Use of uncontaminated marine sediments in mortar and concrete by partial substitution of cement. Cement and Concrete Composites, 93, 155-162.

[3] Z. Zhao*, L. Courard, S. Groslambert, T. Jehin, A. Léonard, J. Xiao (2020). Use of recycled concrete aggregates from block wastes for the production of new concrete blocks: an industrial-scale study. Resources, Conservation and Recycling, 157, 104786.

[4] L. Courard, Z. Zhao*, F. Michel (2021). Influence of hydrophobic product nature and concentration on carbonation resistance of concrete cultural heritage buildings. Cement and Concrete Composites, 115:103860.

[5] Z. Zhao, J. Xiao*, Z. Duan, J. Hubert, S. Grigoletto, L. Courard (2022). Performance and durability of self-compacting mortar with recycled sand from crushed brick. Journal of Building Engineering, 57, 104867.

[6] 赵增丰，姚磊，肖建庄，姬宸源，段珍华，王佃超(2022). 再生骨料CO2碳化强化技术研究进展. 硅酸盐学报, 50(8), 2296-2304.

[7] Z. Zhao*, Y. Liu, Y. Lu*, C. Ji, C. Lin, L. Yao, Z. Pu, J. Brito (2024). Prediction of properties of recycled aggregate concrete using machine learning models: A critical review. Journal of Building Engineering, 90, 109516.

[8] H. Yang, H. Li, Z. Zhao* (2025). Modeling prediction of bond strength between rebar and recycled aggregate concrete by deep learning approach based on attention mechanism. Construction and Building Materials, 471:140753.

[9] Z. Zhao, C. Ji*, J. Wang, L. Zhu, D. Wang, N. Tošić (2025). Investigation of gold mine tailings as supplementary cementitious material: Performance and carbon footprint. Journal of Cleaner Production, 518:145933.

[10] C. Ji, Z. Zhao*, L. Yao, C. Lin, J. Xu, J. Xiao (2025). Potential of using residual tuff mud to produce low-carbon cement mortar. Sustainable Materials and Technologies, 45, e01559.