A spatio-temporal life cycle assessment framework for building renovation scenarios at the urban scale

• Published in: Renewable & sustainable energy reviews Vol. 126; p. 109834
• Main Authors: Mastrucci, Alessio, Marvuglia, Antonino, Benetto, Enrico, Leopold, Ulrich
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.07.2020
• Subjects: Building stock renovation; Carbon footprint; Geographical information systems; Life cycle assessment; Time-adjusted emission accounting; Urban energy planning; Life cycle assessment; Time-adjusted emission accounting; Geographical information systems; Building stock renovation; Urban energy planning; Carbon footprint
• ISSN: 1364-0321; 1879-0690
• DOI: 10.1016/j.rser.2020.109834

Reducing the energy consumption of buildings is a priority for carbon emissions mitigation in urban areas. Building stock energy models have been developed to support decisions of public authorities in renovation strategies. However, the burdens of renovation interventions and their temporal distribution are mostly overlooked, leading to potential overestimation of environmental benefits. Life Cycle Assessment (LCA) provides a holistic estimation of environmental impacts, but further developments are needed to correctly consider spatio-temporal aspects. We propose a spatio-temporal LCA framework to assess renovation scenarios of urban housing stocks, integrating: 1) a geospatial building-by-building stock model, 2) energy demand modelling, 3) product-based LCA, and 4) a scenario generator. Temporal aspects are considered both in the lifecycle inventory and the lifecycle impact assessment phases, by accounting for the evolution of the existing housing stock and applying time-adjusted carbon footprint calculation. We apply the framework for the carbon footprint assessment of housing renovation in Esch-sur-Alzette (Luxembourg). Results show that the renovation stage represents 4%–16% of the carbon footprint in the residual service life of existing buildings, respectively after conventional or advanced renovations. Under current renovation rates, the carbon footprint reduction would be limited to 3–4% by 2030. Pushing renovation rates to 3%, enables carbon reductions up to 28% by 2030 when combined with advanced renovations. Carbon reductions in the operational stage of buildings are offset by 8–9% due to the impacts of renovation. Using time-adjusted emissions results in higher weight for the renovation stage and slightly lower benefits for renovation. •Spatio-temporal Life Cycle Assessment of urban building renovation scenarios.•Renovation scenarios developed for the city of Esch-sur-Alzette (Luxembourg).•The renovation stage holds 4–16% of the carbon emissions in residual service life.•Pushing renovation rate to 3% enables carbon reductions up to 28% by 2030.•Time-adjusted emissions accounting results in higher weight for the renovation stage.