Atmospheric water transport connectivity within and between ocean basins and land

The global atmospheric water transport from the net evaporation to the net precipitation regions has been traced using Lagrangian trajectories. A matrix has been constructed by selecting various group of trajectories based on their surface starting (net evaporation) and ending (net precipitation) positions to show the connectivity of the 3-D atmospheric water transport within and between the three major ocean basins and the global landmass. The analysis reveals that a major portion of the net evaporated water precipitates back into the same region, namely 67 % for the Indian Ocean, 64 % for the Atlantic Ocean, 85 % for the Pacific Ocean and 72 % for the global landmass. It has also been calculated that 58 % of the net terrestrial precipitation was sourced from land evaporation. The net evaporation from the subtropical regions of the Indian, Atlantic and Pacific oceans is found to be the primary source of atmospheric water for precipitation over the Intertropical Convergence Zone (ITCZ) in the corresponding basins. The net evaporated waters from the subtropical and western Indian Ocean were traced as the source for precipitation over the South Asian and eastern African landmass, while Atlantic Ocean waters are responsible for rainfall over North Asia and western Africa. Atlantic storm tracks were identified as the carrier of atmospheric water that precipitates over Europe, while the Pacific storm tracks were responsible for North American, eastern Asian and Australian precipitation. The bulk of South and Central American precipitation is found to have its source in the tropical Atlantic Ocean. The land-to-land atmospheric water transport is pronounced over the Amazon basin, western coast of South America, Congo basin, northeastern Asia, Canada and Greenland. The ocean-to-land and land-to-ocean water transport through the atmosphere was computed to be 2×10^9 and 1×10^9 kg s^−1, respectively. The difference between them (net ocean-to-land transport), i.e. 1×10^9 kg s^−1, is transported to land. This net transport is approximately the same as found in previous estimates which were calculated from the global surface water budget.

10.5194/hess-27-481-2023

1607-7938

481–493

Dey, Dipanjan

6abca563-f99d-4554-a0b8-945d5621b16b

Aldama Campino, Aitor

08173a04-3913-450f-aea2-5ba8fe36438e

Döös, Kristofer

f983e388-b9e9-4405-a51d-adf432410c2e

24 January 2023

Dey, Dipanjan

6abca563-f99d-4554-a0b8-945d5621b16b

Aldama Campino, Aitor

08173a04-3913-450f-aea2-5ba8fe36438e

Döös, Kristofer

f983e388-b9e9-4405-a51d-adf432410c2e

Dey, Dipanjan, Aldama Campino, Aitor and Döös, Kristofer (2023) Atmospheric water transport connectivity within and between ocean basins and land. Hydrology and Earth System Sciences, 27 (2), 481–493. (doi:10.5194/hess-27-481-2023).

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Accepted/In Press date: 16 January 2023

Published date: 24 January 2023

Additional Information: Funding Information: This research has been supported by the Vetenskapsrådet (grant no. 2019-03574). The article processing charges for this open-access publication were covered by Stockholm University. Funding Information: The authors wish to acknowledge Peter Lundberg and Sara Berglund for their constructive comments. This work has been financially supported by the Swedish Research Council through grant agreement no. 2019-03574. The TRACMASS model integrations and the Lagrangian trajectory computations were performed on resources provided by the Swedish National Infrastructure for Computing (SNIC) at the National Supercomputer Centre (NSC) partially funded by the Swedish Research Council through grant agreement no. 2018-05973. Publisher Copyright: © 2023 Copernicus GmbH. All rights reserved.