| Title | Implementation at a city level of circular economy strategies and climate change mitigation - the case of Brussels |
|---|---|
| ID_Doc | 5822 |
| Authors | Christis, M; Athanassiadis, A; Vercalsteren, A |
| Title | Implementation at a city level of circular economy strategies and climate change mitigation - the case of Brussels |
| Year | 2019 |
| Published | |
| Abstract | Within the framework of the 2015 Paris Agreement and the increased acceptance of circular economy (CE) principles of national and local governments, it is essential to study the potential effect on climate change of CE-strategies implemented on an urban scale. The present research quantitatively assesses the potential impact of these strategies on primary material footprint (MF) and carbon footprint (CF) of households in areas an urban area, using the case of Brussels Capital Region (BCR), Belgium. Because the CE-strategies are linked to consumption domains, this assessment first calculates both footprints of consumption domains using a city-level input-output analysis and discusses the relationship between the footprints. The findings show that the carbon footprint of BCR in 2010 was 22 Mt CO2-eq. or 20.3 t/cap. The material footprint of BCR in 2010 was 31 Mt or 29.5 t/cap. Important insights are that BCR relies on its hinterland for 98% of its primary materials and 83% of the region's greenhouse gas emissions (GHGs) are emitted outside of its territory. The household consumption domains of food, housing and transport were identified as hotspots in both footprints. Within these domains, we calculated and discussed the potential impact on both footprints of CE-strategies on consumption or production of food, mobility and housing. Results from this case show that with these strategies Brussels could mitigate 25% of its CF and 26% of its MF, 18% of its CF and 26% of its MF, and 7% of its CF and 10% of its MF, respectively. The methodology and insights could therefore support authorities and policy-makers to effectively develop coherent and consistent action plans on consumption domains to improve resource efficiency and reduce the GHGs, simultaneously. (C) 2019 Elsevier Ltd. All rights reserved. |
Similar Articles
| ID | Score | Article |
|---|---|---|
15023
|
Del Borghi, A; Gallo, M; Silvestri, N; Baccelli, O; Croci, E; Molteni, T Impact of circular measures to reduce urban CO2 emissions: An analysis of four case studies through a production- and consumption-based emission accounting method(2022) | |
| 67617
|
Harris, S; Weinzettel, J; Bigano, A; Källmén, A Low carbon cities in 2050? GHG emissions of European cities using production-based and consumption-based emission accounting methods(2020) | |
| 28788
|
Kopp, M; Petit-Boix, A; Leipold, S Municipal circular economy indicators: Do they measure the cities' environmental ambitions?(2024) | |
| 2299
|
Sardianou, E; Nikou, V; Kostakis, I Harmonizing Sustainability Goals: Empirical Insights into Climate Change Mitigation and Circular Economy Strategies in Selected European Countries with SDG13 Framework(2024)Sustainability, 16, 1 | |
| 15393
|
Pulselli, RM; Broersma, S; Martin, CL; Keeffe, G; Bastianoni, S; van den Dobbelsteen, A Future city visions. The energy transition towards carbon-neutrality: lessons learned from the case of Roeselare, Belgium(2021) | |
| 2063
|
Möslinger, M; Ulpiani, G; Vetters, N Circular economy and waste management to empower a climate-neutral urban future(2023) | |
| 16370
|
Mungo, C; Franco-García, ML A Sustainable Supply Chain Perspective in the Transition to Circular Cities(2019) | |
| 20856
|
Campbell-Johnston, K; ten Cate, J; Elfering-Petrovic, M; Gupta, J City level circular transitions: Barriers and limits in Amsterdam, Utrecht and The Hague(2019) | |
| 19396
|
Harris, S; Weinzettel, J; Levin, G Implications of Low Carbon City Sustainability Strategies for 2050(2020)Sustainability, 12.0, 13 | |
| 1668
|
Keblowski, W; Lambert, D; Bassens, D Circular economy and the city: an urban political economy agenda(2020)Culture And Organization, 26, 2 |