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Lookup NU author(s): Dr Hannah BloomfieldORCiD
This work is licensed under a Creative Commons Attribution 4.0 International License (CC BY 4.0).
Atmospheric reanalyses are widely used for understanding the past and present climate. They have become increasingly used within the renewable energy sector for assessing wind and solar resources for different regions of the globe in conjunction with observations. Mexico is a country with considerable potential for wind energy production, especially around coastal sites and therefore the characterization of wind resource in these areas of the country is imperative for the most beneficial use of these resources. In this study, we assess how well three global reanalyses, namely ERA-Interim, ERA5 and MERRA-2, can reproduce wind observations at a number of key sites across the country. We find that the reanalyses' ability to reproduce these observations is highly variable between different regions in Mexico. Correlation coefficients are around 0.9 in the south of the country where the winds are strongest, but much lower (around 0.5) in Baja California Sur due to the complex coastal topography of the region. ERA5 outperforms ERA-Interim and MERRA-2 consistently across the vast majority of sites and so this reanalysis is recommended for local wind power studies. The consistently improved performance compared with ERA-Interim shows the value of the increased spatial resolution of ERA5. However, in the south and east of Mexico, despite having the highest correlations, ERA5 also has the largest bias, meaning that it underestimates winds consistently across most of the country. Poor correlations between ERA5 and the observations in Veracruz are considered as a case study to understand potential drivers of low wind biases.
Author(s): Thomas SR, Nicolau S, Martinez-Alvarado O, Drew DJ, Bloomfield HC
Publication type: Article
Publication status: Published
Journal: Meteorological Applications
Year: 2021
Volume: 28
Issue: 5
Online publication date: 07/09/2021
Acceptance date: 26/07/2021
Date deposited: 09/10/2024
ISSN (print): 1350-4827
ISSN (electronic): 1469-8080
Publisher: Royal Meteorological Society
URL: https://doi.org/10.1002/met.2023
DOI: 10.1002/met.2023
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