References
- Ayat, A., Bouzerd, H., Ali-Boucetta, T., Navarro, A., & Benmalek, M. L. (2020). Valorisation of waste glass powder and brick dust in air-lime mortars for restoration of historical buildings: Case study theatre of Skikda (Northern Algeria). Construction and Building Materials, 315, 125681.
- Adesina, A., de Azevedo, A. R., Amin, M., Hadzima-Nyarko, M., Agwa, I. S., Zeyad, A. M., & Tayeh, B. A. (2021). Fresh and mechanical properties overview of alkali-activated materials made with glass powder as precursor. Cleaner Materials, 3, 100036.
- Almeshal, I., Al-Tayeb, M. M., Qaidi, S. M., Bakar, B. A., & Tayeh, B. A. (2022). Mechanical properties of eco-friendly cements-based glass powder in aggressive medium. Materials Today: Proceedings, 58, 1582-1587.
- Ashiq, S. Z., Akbar, A., Farooq, K., Kazmi, S. M. S., & Munir, M. J. (2022). Suitability assessment of marble, glass powders and poly-propylene fibers for improvement of siwalik clay. Sustainability, 14(4), 2314.
- Buitrago-Rincon, D. L., Sadtler, V., Mercado, R. A., Roques-Carmes, T., Benyahia, L., Durand, A. & Lemaitre, C. (2021). Effect of Silica Nanoparticles in Xanthan Gum Solutions: Evolution of Viscosity over Time. Nanomaterials, 12(11), 1906.
- Crugeira, P. J., de Almeida, P. F., Sampaio, I. C., Soares, L. G., Amador, D. A. M., Samuel, I. D., ... & Pinheiro, A. L. (2021). Production and viscosity of Xanthan Gum are increased by LED irradiation of X. campestris cultivated in medium containing produced water of the oil industry. Journal of Photochemistry and Photobiology B: Biology, 226, 112356.
- Chu, S. H., Li, L., Shen, P. L., Lu, J. X., & Poon, C. S. (2020). Recycling of waste glass powder as paste replacement in green UHPFRC. Construction and Building Materials, 316, 125719.
- De Souza, E. R., Rodrigues, P. D., Sampaio, I. C., Bacic, E., Crugeira, P. J., Vasconcelos, A. C., ... & de Almeida, P. F. (2022). Xanthan gum produced by Xanthomonas campestris using produced water and crude glycerin as an environmentally friendlier agent to enhance oil recovery. Fuel, 310, 122421.
- Dzionek, A., Wojcieszyńska, D., & Guzik, U. (2021). Use of xanthan gum for whole cell immobilization and its impact in bioremediation-a review. Bioresource Technology, 126918.
- Derinpinar, A. N., Karakoç, M. B., & Özcan, A. (2020). Performance of glass powder substituted slag based geopolymer concretes under high temperature. Construction and Building Materials, 331, 127318.
- Hendi, A., Mostofinejad, D., Sedaghatdoost, A., Zohrabi, M., Naeimi, N., & Tavakolinia, A. (2019). Mix design of the green self-consolidating concrete: Incorporating the waste glass powder. Construction and Building Materials, 199, 369-384.
- Ibrahim, S., & Meawad, A. (2020). Towards green concrete: Study the role of waste glass powder on cement/superplasticizer compatibility. Journal of Building Engineering, 47, 103751.
- Jiang, X., Xiao, R., Bai, Y., Huang, B., & Ma, Y. (2022). Influence of waste glass powder as a supplementary cementitious material (SCM) on physical and mechanical properties of cement paste under high temperatures. Journal of Cleaner Production, 340, 130778.
- Kusnezoff, M., Wagner, D., Schilm, J., Heubner, C., Matthey, B., & Lee, C. W. (2022). Influence of microstructure and crystalline phases on impedance spectra of sodium conducting glass ceramics produced from glass powder. Journal of Solid State Electrochemistry, 26(2), 375-388.
- Kongjaroen, A., Methacanon, P., Seetapan, N., Fuongfuchat, A., Gamonpilas, C., & Nishinari, K. (2020). Effects of dispersing media on the shear and extensional rheology of xanthan gum and guar gum-based thickeners used for dysphagia management. Food Hydrocolloids, 107857.
- Lee, H., Hanif, A., Usman, M., Sim, J., & Oh, H. (2018). Performance evaluation of concrete incorporating glass powder and glass sludge wastes as supplementary cementing material. Journal of Cleaner Production, 170, 683-693.
- Mejdi, M., Wilson, W., Saillio, M., Chaussadent, T., Divet, L., & Tagnit-Hamou, A. (2019). Hydration and microstructure of glass powder cement pastes–A multi-technique investigation. Cement and Concrete Research, 151, 106610.
- Mohammed, T. K., & Hama, S. M. (2021). Mechanical properties, impact resistance and bond strength of green concrete incorporating waste glass powder and waste fine plastic aggregate. Innovative Infrastructure Solutions, 7(1), 1-12.
- Mahmood, A. H., Afroz, S., Kashani, A., Kim, T., & Foster, S. J. (2022). The efficiency of recycled glass powder in mitigating the alkali-silica reaction induced by recycled glass aggregate in cementitious mortars. Materials and Structures, 55(6), 1-20.
- Mota, G. P., & Pereira, R. G. (2022). A comparison of the rheological behavior of xanthan gum and diutan gum aqueous solutions. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 44(4), 1-11.
- Manikandan, P., Natrayan, L., Duraimurugan, S., & Vasugi, V. (2019). Influence of waste glass powder as an aluminosilicate precursor in synthesizing ternary blended alkali-activated binder. Silicon, 1-10.
- Nsengiyumva, E. M., & Alexandridis, P. (2022). Xanthan gum in aqueous solutions: Fundamentals and applications. International Journal of Biological Macromolecules.
- Onaizi, A. M., Lim, N. H. A. S., Huseien, G. F., Amran, M., & Ma, C. K. (2020). Effect of the addition of nano glass powder on the compressive strength of high volume fly ash modified concrete. Materials Today: Proceedings, 48, 1789-1795.
- Kala kado H., A.,(2022). Performance of glass-powder concrete in field applications. Construction and Building Materials, 109, 84-95.
- Sadiqul, M., Zahrai, S. M., & Najaf, E. (2021, October). Effect of glass powder & polypropylene fibers on compressive and flexural strengths, toughness and ductility of concrete: An environmental approach. In Structures (Vol. 33, pp. 4616-4628). Elsevier.
- Patel, D., Tiwari, R. P., Shrivastava, R., & Yadav, R. K. (2019). Effective utilization of waste glass powder as the substitution of cement in making paste and mortar. Construction and Building Materials, 199, 406-415.
- Szudek, W., Gołek, Ł., Malata, G., & Pytel, Z. (2019). Influence of waste glass powder addition on the microstructure and mechanical properties of autoclaved building materials. Materials, 15(2), 434.
- Sadiqul G.M., Rahman M.H., Nayem K. (2017) “Waste Glass Powder As Partial Replacement Of Cement For Sustainable Concrete Practice’’, International Journal Of Sustainable Built Environment,Volume 6, pp 37–44.
- Tho-In, T., Sata, V., Boonserm, K., & Chindaprasirt, P. (2018). Compressive strength and microstructure analysis of geopolymer paste using waste glass powder and fly ash. Journal of cleaner production, 172, 2892-2898.
- Orouji, T., (2021). Compressive strength and microstructure analysis of geopolymer paste using waste glass powder and fly ash. Journal of cleaner production, 172, 2892-2898.
- Wang, Y., Li, Y., Su, Y., He, X., & Strnadel, B. (2019). Preparation of waste glass powder by different grinding methods and its utilization in cement-based materials. Advanced Powder Technology, 33(8), 103690.
- Zhan, P. M., Zhang, X. X., He, Z. H., Shi, J. Y., Gencel, O., Yen, N. T. H., & Wang, G. C. (2020). Strength, microstructure and nanomechanical properties of recycled aggregate concrete containing waste glass powder and steel slag powder. Journal of Cleaner Production, 341, 130892.
- Zhang, T., Lu, Z., Sun, Z., Yang, H., Yan, Z., & Ji, Y. (2021). Modification of glass powder and its effect on the compressive strength of hardened alkali-activated slag-glass powder paste. Journal of Building Engineering, 105030.