Reddy, S., Peera, K., Surendra, A., Arvind kumar, C., Leelakar, M. (2025). Role of nano-Al2O3 in modifying the properties of ultra high performance concrete. , 18(1), 72-77. doi: 10.30772/qjes.2024.153324.1376
S. Hariprasad Reddy; K Mahaboob Peera; A. Surendra; Cholker Arvind kumar; Meruva Leelakar. "Role of nano-Al2O3 in modifying the properties of ultra high performance concrete". , 18, 1, 2025, 72-77. doi: 10.30772/qjes.2024.153324.1376
Reddy, S., Peera, K., Surendra, A., Arvind kumar, C., Leelakar, M. (2025). 'Role of nano-Al2O3 in modifying the properties of ultra high performance concrete', , 18(1), pp. 72-77. doi: 10.30772/qjes.2024.153324.1376
Reddy, S., Peera, K., Surendra, A., Arvind kumar, C., Leelakar, M. Role of nano-Al2O3 in modifying the properties of ultra high performance concrete. , 2025; 18(1): 72-77. doi: 10.30772/qjes.2024.153324.1376

Role of nano-Al2O3 in modifying the properties of ultra high performance concrete

Al-Qadisiyah Journal for Engineering Sciences
Article 11, Volume 18, Issue 1, March 2025, Pages 72-77    PDF (9.17 M)
Document Type: Research Paper
DOI: 10.30772/qjes.2024.153324.1376
Authors
S. Hariprasad Reddy* 1; K Mahaboob Peera1; A. Surendra1; Cholker Arvind kumar2; Meruva Leelakar3
1Department of Civil Engineering, Srinivasa Ramanujan Institute of Technology, Ananthapuramu, India.
2Department of Civil Engineering, Matrusri Engineering College, Hyderabad, Telangana, India.
3Department of Civil Engineering, Sri Venkateswara College of Engineering and Technology, Chittoor, India.
Abstract
The purpose of this study is to use cutting-edge nano modification technology to provide a crucial foundation for utilizing new-generation cementitious materials with extremely high strength and extremely extended service life. This research addresses the effects of nano Al2O3 particles replacement on the UHPC. In this research, nano Al2O3 particles mixes were used as additive ranges from 0, 0.5, 1, 1.5, 2, 2.5, and 3 percent from cement weight in UHPC. Concrete was prepared to perform slump cone, strength, modulus of elasticity, water permeability, and SEM analysis.
The results indicated that the nano Al2O3 particles enhanced the flowability and increased the heat of hydration with the increase of their contents. It shows that nano Al2O3 particles can significantly accelerate the setting and hardening process of UHPC. The optimal dosages to enhance mechanical and durability properties were 2% nano Al2O3 particles. The compressive strengths of specimen increased by 26.86% compared to the control mix., it also reduced the 37.04% depth of water penetration under pressure, respectively in comparison to control concrete. The results exhibit that the nano Al2O3 particle is an excellent filler material, reducing porosity regions and accelerating cement hydration via the pozzolanic effect. The SEM analysis demonstrated that adding nano Al2O3 particles may also effectively enhance the interfacial transition zone.
Keywords
Nano-materials; Workability; Mechanical properties; Durability performance; A12O3 particles
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