Materials and service lives alterations impacts on reducing the whole life embodied carbon of buildings: A case study of a student accommodation development in Ireland
Moran, Paul Flynn, Jack Larkin, Conor Goggins, Jamie Elkhayat, Youssef
Moran, Paul
Flynn, Jack
Larkin, Conor
Goggins, Jamie
Elkhayat, Youssef
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Publication Date
2025-03-13
Type
journal article
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Citation
Moran, Paul, Flynn, Jack, Larkin, Conor, Goggins, Jamie, & Elkhayat, Youssef. (2025). Materials and service lives alterations impacts on reducing the whole life embodied carbon of buildings: A case study of a student accommodation development in Ireland. Case Studies in Construction Materials, 22, e04514. https://doi.org/10.1016/j.cscm.2025.e04514
Abstract
To meet the growing demand for student accommodations and fulfil climate change targets, it is essential to establish a methodology for evaluating and reducing their whole-life embodied carbon (WLEC) emissions. The study aims to develop a robust methodology for assessing and reducing the WLEC emissions of a new student accommodation development in Ireland as a replicable case study for other countries. The developed method is based on EN 15978 building whole life cycle standard and EU Level(s) framework. The reduction methodology based on hotspot analysis identifies the most impactful life cycle modules and materials. WLEC assessments were performed on an actual project with two base case scenarios: blockwork (BW) walls for the tender stage and precast walls (PC) for the as-built stage. The WLEC emissions were 749 kgCO2e/m2 for the BW and 838 kgCO2e/m2 for the PC. The production stage modules (A1-A3) and the replacement module (B4) were the primary contributors, with 56 % and 34 %, respectively. The proposed WLEC reduction methodology altered the concrete and the rebar with lower EC alternatives available in the Irish market. It modified the service life of seven building elements to align with the manufacturer's standards. Consequently, the WBEC emissions were reduced by 27 % and 33 % for the BW and PC scenarios. This methodology promotes low-EC and durable alternatives to replace conventional materials for the upcoming student accommodation projects in Ireland to achieve the Climate Action Plan EC reduction target by 2030.
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Publisher
Elsevier
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Attribution 4.0 International