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Keywords

Palm frond waste ash Cost, effective mortar Sustainable binders Microanalysis Supplementary cementitious materials

Document Type

Research Paper

Abstract

Ecological implications posed by the cement industry, biomass ashes, and agricultural waste are growing with emerging concerns. Hence, this paper analyzes and evaluates the characterization of Iraqi date palm frond waste ash (PFWA) and its potential impact on the performance of cement-based mortar. PFWA was utilized to substitute 10, 20, and 30% of the partial weight of cement. The experimental program consists of three main parts: Firstly, the preliminary physicochemical and microanalysis characterization of PFWA powder was investigated and corresponded with the limits of ASTMC-618. Secondly, the compressive and flexural strength, dry density, and water absorption capacity of the fabricated cement-based mortar with the adopted replacement percentages were observed. Finally, the cost analysis of the final products was conducted to obtain a cost-effective evaluation. Generally, the results proved that incorporating 10% PFWA boosts the hardened characteristics. Alternatively, further upgrading of the PFWA content adversely affects the investigated properties. After 28 and 90 days, 10% PFWA boosted the compressive strength by around 15% compared with the control mixture. The cost analysis proves a reduction in the total cost of the mortar by 8.1, 16.1, and 24.1% by replacing 10%, 20%, and 30% of OPC with PFWA. Therefore, using PFWA as SCM in cement-based composites could be a promoted alternative that would benefit the management, recycling, and reusing rate of agricultural waste and support the advancement of sustainability through the construction sector with cost-effective advantages.

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Highlights

Iraqi palm frond waste ash used as a supplementary cementations material (SCM) PFWA showed pozzolanic and cementitious properties due to its elemental composition A 10% PFWA replacement improved the properties of cement-based mortar Caution is advised when increasing PFWA content in cement-based composites

DOI

10.30684/etj.2025.156722.1883

First Page

386

Last Page

400

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