Quantification of the urban water-energy nexus in México City, México, with an assessment of water-system related carbon emissions

Adrián Moredia Valek; Janez Sušnik; Stelios Grafakos

doi:10.1016/j.scitotenv.2017.02.234

Quantification of the urban water-energy nexus in México City, México, with an assessment of water-system related carbon emissions

Sci Total Environ. 2017 Jul 15:590-591:258-268. doi: 10.1016/j.scitotenv.2017.02.234. Epub 2017 Mar 3.

Authors

Adrián Moredia Valek¹, Janez Sušnik², Stelios Grafakos¹

Affiliations

¹ Institute for Housing and Urban Development Studies, Erasmus University Rotterdam, Rotterdam, The Netherlands.
² Integrated Water Systems and Governance Department, UNESCO-IHE Institute for Water Education, Delft, The Netherlands. Electronic address: j.susnik@unesco-ihe.org.

PMID: 28262366
DOI: 10.1016/j.scitotenv.2017.02.234

Abstract

Global urbanisation will put considerable stress on both water and energy resources. While there is much research at the national and regional levels on the energy implications of water supply (the urban water-energy 'nexus'), there is relatively little at the city scale. This literature is further diminished when attempting to account for the climate impact of urban water systems. A study of the urban water-energy-climate nexus is presented for México City. It is shown that 50% of México City water comes from a local aquifer with a further 30% deriving from energy-intensive surface sources which are pumped over considerable topography. The water supply system consumes 90% of the water system energy demand, and is responsible for the majority (90%) of the CO₂e emissions. In the wastewater sector, 80-90% is discharged with no or little treatment, with correspondingly low energy demand. The small fraction that is treated accounts for the majority of energy use in the wastewater sector. This study shows the uncertainty in energy demand and CO₂e emissions when reliant on secondary data which considerably over/under-estimate energy use compared with primary data. This has implications when assessing energy and carbon budgets. Three water savings options are assessed for their impact on energy and CO₂e emissions reductions. Considerable reductions in water supply volumes and concomitant energy consumption and CO₂e emissions are possible. However the extent of implementation, and the effectiveness of any implemented solutions depend on financing, institutional backing and public support. An additional measure to reduce the climate impact is to switch from traditional to renewable fuels. This work adds city-level quantification of the urban water-energy-climate nexus, allowing policy makers to discern which water-system elements are responsible for the greatest energy use and climate impact, and are better equipped to make targeted operational decisions.

Keywords: México City; Water savings measures; Water system CO(2)e emissions; Water-energy nexus.