Contribución de las componentes de la evapotranspiración a la interacción suelo-atmósfera en Sudamérica

Daira A. Rosales; Romina C. Ruscica; Anna A. Sörensson

doi:10.24215/1850468Xe033

Autores/as

Daira A. Rosales Universidad de Buenos Aires, Argentina https://orcid.org/0009-0005-2007-5434
Romina C. Ruscica Universidad de Buenos Aires, Argentina https://orcid.org/0000-0003-0127-9579
Anna A. Sörensson Universidad de Buenos Aires, Argentina https://orcid.org/0000-0001-5093-9655

DOI:

https://doi.org/10.24215/1850468Xe033

Palabras clave:

hotspots de interacción suelo-atmósfera, transpiración, inLand, LPJmL4, evapotranspiración

Resumen

La evapotranspiración es una variable clave del ciclo hidrológico ya que modifica aspectos físicos del sistema climático, cómo la humedad del suelo y de la atmósfera, la cantidad de agua en ríos o acuíferos, y la temperatura del suelo y del aire en superficie. Una correcta representación de la evapotranspiración es de suma importancia para el estudio del sistema climático, por ejemplo para la identificación de eventos extremos como inundaciones o sequías, u olas de calor o de frío. En particular, es de relevancia distinguir regiones de interacción suelo-atmósfera, es decir dónde variaciones en el suelo modifican la atmósfera. En este trabajo investigamos la representación de la evapotranspiración en Sudamérica según cinco estimaciones diferentes: cuatro simulaciones provenientes de dos modelos globales de vegetación dinámica, y un producto satelital, durante el período 1981-2010. Principalmente, estudiamos la partición de la evapotranspiración en sus componentes: transpiración, evaporación desde la vegetación, y desde el suelo; y cómo éstas contribuyen a la interacción suelo-atmósfera en diciembre-enero-febrero. Hallamos que, aunque las estimaciones de la evapotranspiración anual media presentan un patrón espacial similar, no ocurre lo mismo con la partición en componentes. Encontramos regiones de interacción suelo-atmósfera que son reconocidas habitualmente en la literatura: el centro de Argentina y el noreste de Brasil, que son, además, regiones de transición entre climas secos y húmedos. Nuestro resultado principal es que la transpiración es la componente de la evapotranspiración que más contribuye a la interacción suelo-atmósfera.

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