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Original Article
Evaluation of Sugarcane Bagasse ash as a bio-based admixture in concrete
Sanjana R1
Kothare2
A. B Dehane3
1PG Student, Department of Civil Engineering, Bapurao Deshmukh College of Engineering, Sewagram, Wardha, Maharashtra, India. 2Assistant Professor, Department of Civil Engineering, Bapurao Deshmukh College of Engineering, Sewagram, Wardha, Maharashtra, India.
Published Online: May-June 2025
Pages: 17-29
Cite this article
↗ https://www.doi.org/10.59256/ijrtmr.20250503002
References
1. Md. Habibur Rahman Sobuz a, *, Al-Imran a, Shuvo Dip Datta a, Jannat Ara Jabin a, Fahim Shahriar Aditto a, Noor Md. Sadiqul
Hasan b, Mahamudul Hasan a, Ahmad Akib Uz Zaman. Assessing the influence of sugarcane bagasse ash for the production of eco-
friendly concrete: Experimental and machine learning approaches (2024)
2. Yuvraj Rathaur, Yash shukla, Arpita Yadav, Anand Bhatt. Experimental Study of Sugarcane Bagasse Ash in Concrete (2023)
3. Kidist Dereje BEDADA 1, Andrew Onderi NYABUTO 2, Ismael Kithinji KINOTI *3, Joseph Mwiti MARANGU Review on advances in
bio-based admixtures for concrete J Sustain Const Mater Technol, Vol. 8, Issue. 4, pp. 344–367, December (2023)
4. Neto, J.; de França, M.S.; Júnior, N.; Ribeiro, D. Effects of adding sugarcane bagasse ash on the properties and durability of concrete.
Constr. Build. Mater. 2021, 266, 120959. (2022)
5. Loganayagan, S.; Mohan, N.C.; Dhivyabharathi, S. Sugarcane bagasse ash as alternate supplementary cementitious material in
concrete. Mater. Today Proc. (2021), 45, 1004–1007.
6. Bayapureddy, Y.; Muniraj, K.; Mutukuru, M.R.G. Sugarcane bagasse ash as supplementary cementitious material in cement composites:
Strength, durability, and microstructural analysis. J. Korean Ceram. Soc. (2020), 57, 513–519.
7. Juenger, M.C.G.; Snellings, R.; Bernal, S.A. Supplementary cementitious materials: New sources, characterization, and perfor mance
insights. Cem. Concr. Res. (2019), 122, 257–273.
8. Kühne, H., Mbugua, R., Ngassam, T. I. L., Olonade, K. A., & Schmidt, W. (2018). Plant-based chemical admixtures - potentials and
effects on the perfor mance of cementitious materials. RILEM Tech Lett, 3, 124–128.
9. Bartholin, M. C., Biasotti, B., Giudici, M., Govin, A., Grosseau, P., & Langella, V. (2016). Modification of water retention and
rheological properties of fresh state cement-based mortars by guar gum deriva tives. Constr Build Mater, 122, 772–780.
10. Otoko, G. R. (2014). Concrete admixture and set re tarder potential of palm liquor. Eur Int J Sci Technol, 3(2), 74–80. [45] Kulkarni,
P., & Muthadhi, A. (2017). Seaweed as an internal curing agent & strengthening in concrete – A Review. Int J Civ Eng, 4, 95–98.
11. He, Z., Li, Y., Lyu, Z., Shen, A., Wang, W., & Wu, H. (2020). Effect of wollastonite microfibers as cement replacement on the properties
of cemen titious composites: A review. Constr Build Mater, 261, 119920.
12. Chege, J., Mang’uriu, G., & Oyawa, W. (2014). The effects of pine (pinus canariensis) tree bark extract on the properties of fresh and
hardened concrete. Civ Env Res, 6, 70–81.
13. Naqi, A.; Jang, J.G. Recent progress in green cement technology utilizing low carbon emission fuels and raw materials: A Review.
Sustainability 2019, 11, 537
14. Moussa, R.; Micheal, A. Evaluating the Effect of Adding Sugarcane Bagasse to the Fire Clay Brick’s Properties. In Architectural
Engineering; BUE University: El Sherouk, Egypt, 2022; Volume 10.
15. Ganesan, K.; Rajagopal, M.; Thangavel, K. Evaluation of bagasse ash as supplementary cementitious material. Cem. Concr. Compos.
2007, 29, 515–524.
16. Nuntachai, C.; Chai, J.; Kraiwood, K. Utilization of bagasse ash as a pozzolanic material in concrete. Constr. Build. Mater. 2009, 23,
3352–3358.
17. IS code 10262-2019 Concrete Mix Design
18. IS 269: 2013 ordinary portland cement, 33 grade — specification
19. IS 456-2000 Design reinforced cement concrete
Hasan b, Mahamudul Hasan a, Ahmad Akib Uz Zaman. Assessing the influence of sugarcane bagasse ash for the production of eco-
friendly concrete: Experimental and machine learning approaches (2024)
2. Yuvraj Rathaur, Yash shukla, Arpita Yadav, Anand Bhatt. Experimental Study of Sugarcane Bagasse Ash in Concrete (2023)
3. Kidist Dereje BEDADA 1, Andrew Onderi NYABUTO 2, Ismael Kithinji KINOTI *3, Joseph Mwiti MARANGU Review on advances in
bio-based admixtures for concrete J Sustain Const Mater Technol, Vol. 8, Issue. 4, pp. 344–367, December (2023)
4. Neto, J.; de França, M.S.; Júnior, N.; Ribeiro, D. Effects of adding sugarcane bagasse ash on the properties and durability of concrete.
Constr. Build. Mater. 2021, 266, 120959. (2022)
5. Loganayagan, S.; Mohan, N.C.; Dhivyabharathi, S. Sugarcane bagasse ash as alternate supplementary cementitious material in
concrete. Mater. Today Proc. (2021), 45, 1004–1007.
6. Bayapureddy, Y.; Muniraj, K.; Mutukuru, M.R.G. Sugarcane bagasse ash as supplementary cementitious material in cement composites:
Strength, durability, and microstructural analysis. J. Korean Ceram. Soc. (2020), 57, 513–519.
7. Juenger, M.C.G.; Snellings, R.; Bernal, S.A. Supplementary cementitious materials: New sources, characterization, and perfor mance
insights. Cem. Concr. Res. (2019), 122, 257–273.
8. Kühne, H., Mbugua, R., Ngassam, T. I. L., Olonade, K. A., & Schmidt, W. (2018). Plant-based chemical admixtures - potentials and
effects on the perfor mance of cementitious materials. RILEM Tech Lett, 3, 124–128.
9. Bartholin, M. C., Biasotti, B., Giudici, M., Govin, A., Grosseau, P., & Langella, V. (2016). Modification of water retention and
rheological properties of fresh state cement-based mortars by guar gum deriva tives. Constr Build Mater, 122, 772–780.
10. Otoko, G. R. (2014). Concrete admixture and set re tarder potential of palm liquor. Eur Int J Sci Technol, 3(2), 74–80. [45] Kulkarni,
P., & Muthadhi, A. (2017). Seaweed as an internal curing agent & strengthening in concrete – A Review. Int J Civ Eng, 4, 95–98.
11. He, Z., Li, Y., Lyu, Z., Shen, A., Wang, W., & Wu, H. (2020). Effect of wollastonite microfibers as cement replacement on the properties
of cemen titious composites: A review. Constr Build Mater, 261, 119920.
12. Chege, J., Mang’uriu, G., & Oyawa, W. (2014). The effects of pine (pinus canariensis) tree bark extract on the properties of fresh and
hardened concrete. Civ Env Res, 6, 70–81.
13. Naqi, A.; Jang, J.G. Recent progress in green cement technology utilizing low carbon emission fuels and raw materials: A Review.
Sustainability 2019, 11, 537
14. Moussa, R.; Micheal, A. Evaluating the Effect of Adding Sugarcane Bagasse to the Fire Clay Brick’s Properties. In Architectural
Engineering; BUE University: El Sherouk, Egypt, 2022; Volume 10.
15. Ganesan, K.; Rajagopal, M.; Thangavel, K. Evaluation of bagasse ash as supplementary cementitious material. Cem. Concr. Compos.
2007, 29, 515–524.
16. Nuntachai, C.; Chai, J.; Kraiwood, K. Utilization of bagasse ash as a pozzolanic material in concrete. Constr. Build. Mater. 2009, 23,
3352–3358.
17. IS code 10262-2019 Concrete Mix Design
18. IS 269: 2013 ordinary portland cement, 33 grade — specification
19. IS 456-2000 Design reinforced cement concrete
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