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A Comparative Study of Optimised Embodied Carbon and Cost in RC Slab Structures

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  • Chia Paknahad

    (Department of Civil Engineering and Built Environment, School of Computing and Engineering, University of West London, London W5 5RF, UK)

  • Mosleh Tohidi

    (Department of Civil Engineering and Built Environment, School of Computing and Engineering, Croydon University Centre, Croydon, London CR9 1DX, UK)

  • Ali Bahadori-Jahromi

    (Department of Civil Engineering and Built Environment, School of Computing and Engineering, University of West London, London W5 5RF, UK)

  • Shah Room

    (Department of Civil Engineering and Built Environment, School of Computing and Engineering, University of West London, London W5 5RF, UK)

Abstract

Following World War II, the rapid expansion of construction led to intensive use of natural resources, leading to resource depletion and accelerating climate change. Prioritising sustainability in structural design has therefore become essential. This study investigates three reinforced concrete (RC) slab systems typical of office buildings: flat slab, beam and slab, and two-way joist slab, using Eurocode 2 design principles. A 3 × 3 bay model with spans from 4 m to 14 m and three concrete grades (C25/30, C32/40, C40/50) was analysed through nonlinear finite element modelling. The methodology uniquely combines structural optimisation with embodied carbon and cost assessments across multiple slab typologies and span configurations, an approach rarely addressed in prior research. Results show that two-way joist slabs achieve the most favourable balance, reducing embodied carbon by 25–35% and construction cost by up to 15% compared to flat and beam and slab systems. This advantage is particularly evident at spans of 10 m or more, where the ribbed geometry significantly reduces concrete volume. Flat slabs are cost-efficient for short spans of up to 8 m but incur up to 40% higher carbon at longer spans due to increased thickness and punching shear reinforcement requirements. Beam and slab systems consistently recorded the highest cost and carbon values, offering limited environmental benefits despite their structural stiffness. The findings provide practical guidance for span-sensitive slab selection in early design, enabling the delivery of reinforced concrete buildings that are both cost-effective and environmentally responsible.

Suggested Citation

  • Chia Paknahad & Mosleh Tohidi & Ali Bahadori-Jahromi & Shah Room, 2025. "A Comparative Study of Optimised Embodied Carbon and Cost in RC Slab Structures," Sustainability, MDPI, vol. 17(19), pages 1-28, September.
    • Handle: RePEc:gam:jsusta:v:17:y:2025:i:19:p:8662-:d:1758984
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    References listed on IDEAS

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    1. Jim Hart & Bernardino D'Amico & Francesco Pomponi, 2021. "Whole‐life embodied carbon in multistory buildings: Steel, concrete and timber structures," Journal of Industrial Ecology, Yale University, vol. 25(2), pages 403-418, April.
    2. Iman Faridmehr & Moncef L. Nehdi & Mehdi Nikoo & Kiyanets A. Valerievich, 2021. "Predicting Embodied Carbon and Cost Effectiveness of Post-Tensioned Slabs Using Novel Hybrid Firefly ANN," Sustainability, MDPI, vol. 13(21), pages 1-30, November.
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