Coupling of Material Flow Analysis and Life Cycle Assessment to Analyze the Urban Metabolism of a Swedish City

Sammanfattning: Cities are responsible for an increasingly large share of environmental impacts linked to their resource consumption and production of waste. Understanding how the flows of materials and energy in urban systems contribute to environmental impacts is fundamental for urban sustainability. The combination of Material and Energy Flow Analysis (MEFA) and Life Cycle Assessment (LCA) allows an in-depth evaluation of the city’s metabolism by quantifying the environmental impacts of these flows from a life cycle perspective. This method provides a global perspective on the environmental impacts of the studied system and helps avoiding unintended tradeoffs between life cycle stages or between different types of environmental impact.  This thesis aims to analyze the urban metabolism of the city of Umeå by using a simplified MEFA- LCA methodology. The simplified method aims to evaluate urban metabolism based on the available data, without requiring intensive data inventory, and thus can be a powerful tool to assess the sustainability of cities that have not previously been studied, and for which detailed data on material flows are not available, like in the case of Umeå. The MEFA method was used to identify and quantify the most important flows for 5 main sectors in Umeå’s metabolism: households, construction, transportation, wastewater and solid waste treatment. Then, the environmental impacts of these flows throughout their life cycles were quantified with the LCA methodology. Life cycle inventory data were taken from processes available on the Ecoinvent and Agri-footprint databases, and the impact assessment was done using the ReCiPe midpoint method, considering all impact categories to provide a broader view of the environmental impacts.  The results from the application of the MEFA-LCA methodology provided different but complementary information on the city’s metabolism. The households are responsible for most of the material flows, with water being the most relevant flow, while the transportation sector is responsible for most of the energy flows in the form of fuels. The LCA analysis showed that the households and the transportation sector are responsible for the largest share of the environmental impacts. The flow of manufactured materials is the most relevant for the households sector, followed by energy and foods and drinks. In the transportation sector, private passenger cars and air travel correspond to the largest share of impacts in all categories. Regarding the other three sectors, in the construction sector, concrete and cement represent the material flow with the most impact, while the solid waste and wastewater treatment have small contributions to the total environmental impacts.  The analysis performed in this thesis demonstrated that the MEFA-LCA methodology is a useful tool to evaluate the environmental sustainability of a city’s metabolism. It can assess how different sectors and flows contribute to environmental impacts, without requiring exhaustive data. Thus, it can identify key sectors and flows that should be prioritized when developing strategies or planning future research.