Impact of Sulfate in the Sand on the Compressive Strength of Metakaolin-Based Geopolymer Mortar

محتوى المقالة الرئيسي

Sara Y. Thamer
Layth A. Al- Jaberi

الملخص

The advancement of cement alternatives in the construction materials industry is fundamental to sustainable development. Geopolymer is the optimal substitute for ordinary Portland cement, which produces 80% less CO2 emissions than ordinary Portland cement. Metakaolin was used as one of the raw materials in the geopolymerization process. This research examines the influence of three different percentages of sulfate (0.00038, 1.532, and 16.24) % in sand per molarity of NaOH on the compressive strength of metakaolin-based geopolymer mortar (MK-GPM). Samples were prepared with two different molarities (8M and 12M) and cured at room temperature. The best compressive strength value (56.98MPa) was recorded with 12M with lower sulfate content (0.00038%) at 28 days. Also, an inverse relationship is recorded between the increasing sulfate percentages in the sand and the compressive strength values of (MK-GPM). A higher reduction in the compressive strength results at 28 days (60.88% per 8M/NaOH) and (62.23% per 12M/NaOH) was associated with a higher percentage of SO3 in the sand (16.24%).

تفاصيل المقالة

كيفية الاقتباس
"Impact of Sulfate in the Sand on the Compressive Strength of Metakaolin-Based Geopolymer Mortar" (2023) مجلة الهندسة, 29(09), ص 45–57. doi:10.31026/j.eng.2023.09.04.
القسم
Articles

كيفية الاقتباس

"Impact of Sulfate in the Sand on the Compressive Strength of Metakaolin-Based Geopolymer Mortar" (2023) مجلة الهندسة, 29(09), ص 45–57. doi:10.31026/j.eng.2023.09.04.

تواريخ المنشور

المراجع

Alcamand, H.A., Borges, P.H., Silva, F.A., and Trindade, A.C.C., 2018. The effect of matrix composition and calcium content on the sulfate durability of metakaolin and metakaolin/slag alkali-activated mortars. Ceramics International, 44(5), pp. 5037-5044.‏ Doi:10.1016/j.ceramint.2017.12.102.‏

Al-Rawi, R.S., Al-Salihi, R.A.W., and Ali, M.H.M., 2002. Effective sulfate content in concrete ingredients. In Challenges of Concrete Construction: Volume 6, Concrete for Extreme Conditions: Proceedings of the International Conference held at the University of Dundee, Scotland, UK on 9–11 September 2002 (pp. 499-506). Thomas Telford Publishing. Doi:10.1680/cfec.31784.0048.

Al-Sammari, M.A. and Rouf, Z.A., 1987. Deterioration of concrete due to sulfate attack in Iraq. 2nd international conference on the deterioration and repair of reinforced concrete in the Arabian Gulf Bahrain.

Amouri, M.S., and Fawzi, N.M., 2022. The Effect of Different Curing Temperatures on the Properties of Geopolymer Reinforced with Micro Steel Fibers. Engineering, Technology and Applied Science Research, 12(1), pp. 8029-8032. Doi:10.48084/etasr.4629.

Amran, M., Debbarma, S., and Ozbakkaloglu, T., 2021. Fly ash-based eco-friendly geopolymer concrete: A critical review of the long-term durability properties. Construction and Building Materials, 270, P. 121857. Doi:10.1016/j.conbuildmat.2020.121857.

ASTM C618-19, 2019. Standard specification for coal fly ash and raw or calcined natural pozzolan for use in concrete. Barr Harbor Drive, West Conshohocken: Annual Book of ASTM Standards.‏

ASTM C494/C494M-17, 2017. Standard Specification for Chemical Admixtures for Concrete. Annual Book of ASTM Standards.‏

ASTM C109/C109M-20, 2020, “Standard Test Method for Compressive Strength of Hydraulic Cement Mortars (Using 2-in. or [50-mm] Cube Specimens)”, ASTM International, West Conshohocken, PA, 2020, DOI: 10.1520/C0109_C0109M-20.

Atahan, H. N., and Dikme, D., 2011. Use of mineral admixtures for enhanced resistance against sulfate attack. Construction and Building Materials, 25(8), pp. 3450-3457. Doi:10.1016/j.conbuildmat.2011.03.036.

Azad, N.M., and Samarakoon, S.M., 2021. Utilization of Industrial By-Products/Waste to Manufacture Geopolymer Cement/Concrete. Sustainability, 13(2), P. 73. Doi:10.3390/su13020873.

Brunetaud, X., Khelifa, M.R., and Al-Mukhtar, M., 2012. Size effect of concrete samples on the kinetics of external sulfate attack. Cement and Concrete Composites, 34(3), pp. 370-376.‏ Doi:10.1016/j.cemconcomp.2011.08.014.‏

Campos, A., López, C.M., and Aguado, A., 2016. Diffusion–reaction model for the internal sulfate attack in concrete. Construction and Building Materials, 102, pp. 531-540.‏ Doi:10.1016/j.conbuildmat.2015.10.177.‏

Chen, K., Wu, D., Xia, L., Cai, Q., and Zhang, Z., 2021. Geopolymer concrete durability subjected to aggressive environments–a review of influence factors and comparison with ordinary Portland cement. Construction and Building Materials, 279, P. 122496 Doi:10.1016/j.conbuildmat.2021.122496.

Chen, K., Wu, D., Yi, M., Cai, Q., and Zhang, Z., 2021. Mechanical and durability properties of metakaolin blended with slag geopolymer mortars used for pavement repair. Construction and Building Materials, 281, P. 122566. Doi:10.1016/j.conbuildmat.2021.122566.

Chen, W., Huang, B., Yuan, Y., and Deng, M., 2020. Deterioration process of concrete exposed to internal sulfate attack. Materials, 13(6), P. 1336. Doi:10.3390/ma13061336.

Chindaprasirt, P., and Rattanasak, U., 2017. Characterization of the high-calcium fly ash geopolymer mortar with hot-weather curing systems for sustainable application. Advanced Powder Technology, 28(9), pp. 2317-2324. Doi:10.1016/j.apt.2017.06.013.

Fawzi, N.M., Abbas, Z.K., and Jaber, H.A., 2015. Influence of internal sulfate attack on some properties of high strength concrete. Journal of Engineering, 21(8), pp. 1-21. Doi:10.31026/j.eng.2015.08.01

Hussein, S.S., 2021. Study Some properties of geopolymer concrete by using sustainable fibers. PhD. Dissertation, Department of Civil Engineering, University of Baghdad.

Iraqi Standard IQS No. 45, 1984. Aggregates from Natural Sources for Concrete and Building Construction. Baghdad, Iraq,

Kanagaraj, B., Lubloy, E., Anand, N., Hlavicka, V., and Kiran, T., 2023. Investigation of physical, chemical, mechanical, and microstructural properties of cement-less concrete–state-of-the-art review. Construction and Building Materials, 365, 130020. Doi:10.1016/j.conbuildmat.2022.130020

Karakoc, M.B., Türkmen, İ., Maraş, M. M., Kantarci, F., and Demirboğa, R., 2016. Sulfate resistance of ferrochrome slag based geopolymer concrete. Ceramics International, 42(1), pp. 1254-1260. Doi:10.1016/j.ceramint.2015.09.058.

Khaled, Z., Mohsen, A., Soltan, A., and Kohail, M., 2023. Optimization of kaolin into Metakaolin: Calcination Conditions, mix design and curing temperature to develop alkali activated binder. Ain Shams Engineering Journal, 14(6), pp. 102142. Doi:10.1016/j.asej.2023.102142

Kheder, G.F., and Assi, D.K., 2010. Limiting total internal sulphates in 15–75 MPa concrete in accordance to its mix proportions. Materials and structures, 43(1), pp. 273-281. Doi:10.1617/s11527-009-9487-x.

Liu, T., Qin, S., Zou, D., and Song, W., 2018. Experimental investigation on the durability performances of concrete using cathode ray tube glass as fine aggregate under chloride ion penetration or sulfate attack. Construction and Building Materials, 163, pp. 634-642. Doi:10.1016/j.conbuildmat.2017.12.135

Lloyd, N., and Rangan, V., 2010. Geopolymer concrete with fly ash. Proceedings of the Second International Conference on sustainable construction Materials and Technologies, pp. 1493-1504. UWM Center for By-Products Utilization.‏

Marvila, M.T., de Azevedo, A.R.G., de Matos, P.R., Monteiro, S.N., and Vieira, C.M.F., 2021. Materials for production of high and ultra-high performance concrete: Review and perspective of possible novel materials. Materials, 14(15), P. 4304. Doi:10.3390/ma14154304

Mas, B., Cladera, A., Del Olmo, T., and Pitarch, F., 2012. Influence of the amount of mixed recycled aggregates on the properties of concrete for non-structural use. Construction and Building Materials, 27(1), pp. 612-622. Doi:10.1016/j.conbuildmat.2011.06.073

Mohammed, Z.A., Al-Jaberi, L.A., and Shubber, A.N., 2021. Polypropylene fibers reinforced geopolymer concrete beams under static loading, part 1: Under-reinforced section. AIP Conference Proceedings, 2372(1), P. 180010. AIP Publishing LLC.‏ Doi:10.1063/5.0065392

Muhsin, Z.F., and Fawzi, N.M., 2021. Effect of fly ash on some properties of reactive powder concrete. Journal of Engineering, 27(11), pp. 32-46. Doi:10.31026/j.eng.2021.11.03.

Prasad B.V., Daniel, A.P., Anand, N., and Yadav, S. K., 2022. Strength and microstructure behaviour of high calcium fly ash based sustainable geo polymer concrete. Journal of Engineering, Design and Technology, 20(2), pp. 436-454. Doi:10.1108/JEDT-03-2021-0178

Shi, C., 2003. Corrosion resistance of alkali-activated slag cement. Advances in cement research, 15(2), pp. 77-81. Doi:10.1680/adcr.2003.15.2.77

Suwan, T., and Fan, M., 2014. Influence of OPC replacement and manufacturing procedures on the properties of self-cured geopolymer. Construction and Building Materials, 73, pp. 551-561.‏ Doi:10.1016/j.conbuildmat.2014.09.065

Voigt, T., Malonn, T., and Shah, S. P., 2006. Green and early age compressive strength of extruded cement mortar monitored with compression tests and ultrasonic techniques. Cement and Concrete Research, 36(5), pp. 858-867. Doi:10.1016/j.cemconres.2005.09.005

Wang, A., Zheng, Y., Zhang, Z., Liu, K., Li, Y., Shi, L., and Sun, D., 2020. The durability of alkali-activated materials in comparison with ordinary Portland cements and concretes: a review. Engineering, 6(6), pp. 695-706. Doi:10.1016/j.eng.2019.08.019.

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