dc.contributorNatl Inst Space Res
dc.contributorIndiana Univ Purdue Univ
dc.contributorUniversidade Estadual Paulista (Unesp)
dc.creatorCurtarelli, Marcelo P.
dc.creatorOgashawara, Igor
dc.creatorAraujo, Carlos A. S.
dc.creatorAlcantara, Enner H. [UNESP]
dc.creatorLorenzzetti, Joao A.
dc.creatorStech, Jose L.
dc.date2015-11-03T15:29:34Z
dc.date2015-11-03T15:29:34Z
dc.date2014-12-01
dc.date.accessioned2023-09-12T07:09:18Z
dc.date.available2023-09-12T07:09:18Z
dc.identifierhttp://onlinelibrary.wiley.com/doi/10.1002/2014JC010288/abstract
dc.identifierJournal Of Geophysical Research-oceans. Washington: Amer Geophysical Union, v. 119, n. 12, p. 8472-8494, 2014.
dc.identifier2169-9275
dc.identifierhttp://hdl.handle.net/11449/130138
dc.identifier10.1002/2014JC010288
dc.identifierWOS:000348452800016
dc.identifier.urihttps://repositorioslatinoamericanos.uchile.cl/handle/2250/8779452
dc.descriptionWe evaluated the impacts of summertime mesoscale convective systems (MCS) on the heat balance and diel surface mixed layer (SML) dynamics of the Brazilian Amazon's Tucurui Hydroelectric Reservoir (THR). We used a synergistic approach that combines in situ data, remote sensing data, and three-dimensional (3-D) modeling to investigate the typical behavior of the components of the heat balance and the SML dynamics. During the study period (the austral summer of 2012-2013), 22 days with MCS activity were identified. These events occurred approximately every 4 days, and they were most frequent during January (50% of the observations). An analysis of local meteorological data showed that when MCS occur, the environmental conditions at THR change significantly (p-value<0.01). The net longwave flux, which was the heat balance component most strongly impacted by MCS, increased more than 32% on days with MCS activity. The daily integrated heat balance became negative (-54 W m(-2)) on MCS days, while the balance was positive (19 W m(-2)) on non-MCS days. In response to the changes in the heat balance, the SML dynamics changed when a MCS was over the THR. The SML depth was typically 28% higher on the days with MCS (approximate to 1.6 m) compared with the days without MCS (approximate to 1.3 m). The results indicate that MCS are one of the main meteorological disturbances driving the heat balance and the mixing dynamics of Amazonian hydroelectric reservoirs during the summer. These events may have implications for the water quality and greenhouse gas emissions of Amazonian reservoirs.
dc.descriptionNorthern Brazil Electric Power Company (ELETRONORTE)
dc.descriptionBrazilian Electricity Regulatory Agency (ANEEL)
dc.descriptionNational Institute of Science and Technology for Climate Change (INCT for Climate Change)
dc.descriptionConselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)
dc.descriptionCoordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)
dc.descriptionNatl Inst Space Res, Remote Sensing Div, Sao Paulo, Brazil
dc.descriptionIndiana Univ Purdue Univ, Dept Earth Sci, Indianapolis, IN 46202 USA
dc.descriptionSao Paulo State Univ, Dept Cartog, Sao Paulo, Brazil
dc.descriptionSao Paulo State Univ, Dept Cartog, Sao Paulo, Brazil
dc.descriptionELETRONORTE: 4500075234
dc.descriptionANEEL: 8000003629
dc.descriptionCNPq: 161233/2013-9
dc.descriptionCNPq: 302538/2014-3
dc.format8472-8494
dc.languageeng
dc.publisherAmer Geophysical Union
dc.relationJournal Of Geophysical Research-oceans
dc.relation2.711
dc.rightsAcesso restrito
dc.sourceWeb of Science
dc.subjectTropical reservoirs
dc.subjectAmazon
dc.subjectMesoscale convective system
dc.subjectHeat balance
dc.subjectSurface mixed layer dynamics
dc.titleInfluence of summertime mesoscale convective systems on the heat balance and surface mixed layer dynamics of a large Amazonian hydroelectric reservoir
dc.typeArtigo


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