From Resource Extraction to Outflows of Wastes and Emissions: The Socioeconomic Metabolism of the Global Economy, 1900-2015

Overview

Journal Glob Environ Change

Date 2019 Jan 26

PMID 30679887

Citations 21

Authors

Fridolin Krausmann

Christian Lauk

Willi Haas

Dominik Wiedenhofer

Affiliations

Soon will be listed here.

Abstract

The size and structure of the socioeconomic metabolism are key for the planet's sustainability. In this article, we provide a consistent assessment of the development of material flows through the global economy in the period 1900-2015 using material flow accounting in combination with results from dynamic stock-flow modelling. Based on this approach, we can trace materials from extraction to their use, their accumulation in in-use stocks and finally to outflows of wastes and emissions and provide a comprehensive picture of the evolution of societies metabolism during global industrialization. This enables outlooks on inflows and outflows, which environmental policy makers require for pursuing strategies towards a more sustainable resource use. Over the whole time period, we observe a growth in global material extraction by a factor of 12 to 89 Gt/yr. A shift from materials for dissipative use to stock building materials resulted in a massive increase of in-use stocks of materials to 961 Gt in 2015. Since materials increasingly accumulate in stocks, outflows of wastes are growing at a slower pace than inputs. In 2015, outflows amounted to 58 Gt/yr, of which 35% were solid wastes and 25% emissions, the reminder being excrements, dissipative use and water vapor. Our results indicate a significant acceleration of global material flows since the beginning of the 21 century. We show that this acceleration, which took off in 2002, was not a short-term phenomenon but continues since more than a decade. Between 2002 and 2015, global material extraction increased by 53% in spite of the 2008 economic crisis. Based on detailed data on material stocks and flows and information on their long-term historic development, we make a rough estimate of what a global convergence of metabolic patterns at the current level in industrialized countries paired with a continuation of past efficiency gains might imply for global material demand. We find that in such a scenario until 2050 average global metabolic rates double to 22 t/cap/yr and material extraction increases to around 218 Gt/yr. Overall the analysis indicates a grand challenge calling for urgent action, fostering a continuous and considerable reduction of material flows to acceptable levels.

Citing Articles

From extraction to end-uses and waste management: Modeling economy-wide material cycles and stock dynamics around the world.

Wiedenhofer D, Streeck J, Wieland H, Grammer B, Baumgart A, Plank B J Ind Ecol. 2024; 28(6):1464-1480.

PMID: 39722871 PMC: 11667652. DOI: 10.1111/jiec.13575.

Life-Cycle Assessment and Environmental Costs of Cement-Based Materials Manufactured with Mixed Recycled Aggregate and Biomass Ash.

Agrela F, Rosales M, Alonso M, Ordonez J, Cuenca-Moyano G Materials (Basel). 2024; 17(17).

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Identifying the spatial heterogeneity of housing financialization in China: Insights from a multiscale geographically weighted regression.

Wang Y, Yue X, Wang M, Huang G Heliyon. 2024; 10(6):e27542.

PMID: 38509928 PMC: 10951547. DOI: 10.1016/j.heliyon.2024.e27542.

Mass-Balance-Consistent Geological Stock Accounting: A New Approach toward Sustainable Management of Mineral Resources.

Simoni M, Drielsma J, Ericsson M, Gunn A, Heiberg S, Heldal T Environ Sci Technol. 2024; 58(2):971-990.

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Social-ecological niche construction for sustainability: understanding destructive processes and exploring regenerative potentials.

Dorninger C, Menendez L, Caniglia G Philos Trans R Soc Lond B Biol Sci. 2023; 379(1893):20220431.

PMID: 37952625 PMC: 10645119. DOI: 10.1098/rstb.2022.0431.

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