EGU21-9079
https://doi.org/10.5194/egusphere-egu21-9079
EGU General Assembly 2021
© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

Climatology and Trends of Climate Extremes of Temperature and Precipitation in Belo Monte Hydropower Plant – Eastern Amazon, Brazil

Wanderson Luiz-Silva1, Pedro Regoto2, Camila Ferreira de Vasconcellos3, Felipe Bevilaqua Foldes Guimarães4, and Katia Cristina Garcia5
Wanderson Luiz-Silva et al.
  • 1Department of Energy Optimization and Environment (DEA), Electrical Energy Research Center (CEPEL), Rio de Janeiro, Brazil (wanderweather@gmail.com)
  • 2School of Atmospheric Science (SAS), Nanjing University of Information Science and Technology (NUIST), Nanjing, China (pedro.regoto@gmail.com)
  • 3Faculty of Engineering (FEN), University of the State of Rio de Janeiro (UERJ), Rio de Janeiro, Brazil (camilafv0305@gmail.com)
  • 4Polytechnic School (POLI), Federal University of Rio de Janeiro (UFRJ), Rio de Janeiro, Brazil (felipe.bevilaqua@poli.ufrj.br)
  • 5Department of Energy Optimization and Environment (DEA), Electrical Energy Research Center (CEPEL), Rio de Janeiro, Brazil (garciak@cepel.br)

This research aims to support studies related to the adaptation capacity of the Amazon region to climate change. The Belo Monte Hydroelectric Power Plant (HPP) is in the Xingu River basin, in eastern Amazonia. Deforestation coupled with changes in water bodies that occurred in the drainage area of Belo Monte HPP over the past few decades can significantly influence the hydroclimatic features and, consequently, ecosystems and energy generation in the region. In this context, we analyze the climatology and trends of climate extremes in this area. The climate information comes from daily data in grid points of 0.25° x 0.25° for the period 1980-2013, available in http://careyking.com/data-downloads/. A set of 17 climate extremes indices based on daily data of maximum temperature (TX), minimum temperature (TN), and precipitation (PRCP) was calculated through the RClimDex software, recommended by the Expert Team on Climate Change Detection and Indices (ETCCDI). The Mann-Kendall and the Sen’s Curvature tests are used to assess the statistical significance and the magnitude of the trends, respectively. The drainage area of the Belo Monte HPP is dominated by two climatic types: an equatorial climate in the north-central portion of the basin, with high temperatures and little variation throughout the year (22°C to 32°C), in addition to more frequent precipitation; and a tropical climate in the south-central sector, which experiences slightly more pronounced temperature variations throughout the year (20°C to 33°C) and presents a more defined wet and dry periods. The south-central portion of the basin exhibits the highest temperature extremes, with the highest TX and the lowest TN of the year occurring in this area, both due to the predominant days of clear skies in the austral winter, as to the advance of intense masses of polar air at this period. The diurnal temperature range is lower in the north-central sector when compared to that in the south-central region since the first has greater cloud cover and a higher frequency of precipitation. The largest annual rainfall volumes are concentrated at the north and west sides (more than 1,800 mm) and the precipitation extremes are heterogeneous across the basin. The maximum number of consecutive dry days increases from the north (10 to 20 days) to the south (90 to 100 days). The annual frequency of warm days and nights is increasing significantly in a large part of the basin with a magnitude ranging predominantly from +7 to +19 days/decade. The annual rainfall shows a predominant elevation sign of up to +200 mm/decade only in the northern part of the basin, while the remainder shows a reduction of up to -100 mm/decade. The duration of drought periods increases in the south-central sector of the basin, reaching up to +13 days/decade in some areas. The results of this study will be used in the future as an important input, together with exposure, sensibility, and local adaptation capacity, to design adaptation strategies that are more consistent with local reality and to the needs of local communities.

How to cite: Luiz-Silva, W., Regoto, P., de Vasconcellos, C. F., Guimarães, F. B. F., and Garcia, K. C.: Climatology and Trends of Climate Extremes of Temperature and Precipitation in Belo Monte Hydropower Plant – Eastern Amazon, Brazil, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-9079, https://doi.org/10.5194/egusphere-egu21-9079, 2021.

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