Journal of Earthquake Science and Soil Dynamic Engineering

Concrete is one of the most widely used building materials in this era due to its affordability and durability. Every year, India uses tonnes of ready-mixed concrete. It is in Roads, Structures, Thruways, Scaffolds, burrows, Dams, Railroad. It was a typical that 3 ton of cement is utilized by every individual on the planet. CO2 prompts an unnatural weather change and it has a significant piece of green-house gases. The cement industry accounts for only 7% of CO2's contribution, which amounts to 65 percent. The majority of produced concrete is consumed by India, China, and the United States. It was assessed that concrete assembling was rising 2.5%. Then again a lot of materials are accessible with which concrete can be supplanted (Wikipedia). It is helping a great deal in decrease of outflow of CO2. For replacement, fly ash, slag, rise husk, and GGBS are utilized. This substantial arranged is known as Geopolymer concrete. GPC is viewed as now complete substitution of concrete. A great deal of studies has been done by specialist that utilization of GGBS in Geopolymer concrete has further developed the strength properties yet its overabundance sum might decrease the strength. It has a set of experiences beginning around 1940 however it isn't so considered normal till now[1].

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Ramamohana, B., Gopinathan, P., & Chandrasekhar, I. Engineering Properties of GGBS & Fly ash Synthesized Geopolymer Concrete at Different Environmental Conditions by Comparing with Conventional Concrete.

Yadav, S. (2018). Experimental Study of GGBS Based Geopolymer Concrete.

Rajini, B., & Rao, A. N. (2014). Mechanical properties of geopolymer concrete with fly ash and GGBS as source materials. International Journal of Innovative Research in Science, Engineering and Technology, 3(9), 15944-15953.

Babu, N. V., Rahul, B. G., & Kumar, Y. H. (2017). Experimental study on strength and durability properties of GPC with GGBS. International Journal of Civil Engineering and Technology, 8(4).

Bhavin, B., Pitroda, J., & Bhavsar, J. J. (2013, December). Geopolymer Concrete and Its Feasibility In India. In Proceedings of National Conference CRDCE13 (pp. 20-21).

Al Bakri, A. M., Kamarudin, H., Bnhussain, M., Nizar, I. K., Rafiza, A. R., & Zarina, Y. (2012). The processing, characterization, and properties of fly ash based geopolymer concrete. Rev. Adv. Mater. Sci, 30(1), 90-97.

Görhan, G., &Kürklü, G. (2014). The influence of the NaOH solution on the properties of the fly ash-based geopolymer mortar cured at different temperatures. Composites part b: engineering, 58, 371-377.

Vignesh, P., & Vivek, K. (2015). An experimental investigation on strength parameters of flyash based geopolymer concrete with GGBS. International Research Journal of Engineering and Technology, 2(2), 135-142.

Suresh, D., & Nagaraju, K. (2015). Ground granulated blast slag (GGBS) in concrete–a review. IOSR journal of mechanical and civil engineering, 12(4), 76-82.