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Fluvial carbon export and CO 2 efflux in representative nested headwater catchments of the eastern La Plata River Basin
Author(s) -
Sorribas Mino Viana,
Motta Marques David,
Castro Nilza Maria dos Reis,
Fan Fernando Mainardi
Publication year - 2017
Publication title -
hydrological processes
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.222
H-Index - 161
eISSN - 1099-1085
pISSN - 0885-6087
DOI - 10.1002/hyp.11076
Subject(s) - hydrology (agriculture) , drainage basin , fluvial , environmental science , carbon cycle , total organic carbon , water quality , surface runoff , carbon fibers , dissolved organic carbon , total inorganic carbon , geology , structural basin , carbon dioxide , environmental chemistry , geomorphology , ecosystem , chemistry , oceanography , ecology , geotechnical engineering , cartography , geography , materials science , organic chemistry , composite number , composite material , biology
This study involved a baseline evaluation of fluvial carbon export and degas rates in three nested rural catchments (1 to 80 km 2 ) in Taboão, a representative experimental catchment of the Upper Uruguay River Basin. Analyses of the carbon content in stream waters and the catchment carbon yield were based on 4‐year monthly in situ data and statistical modeling using the United States Geological Survey load estimator model. We also estimated p CO 2 and degas fluxes using carbonate equilibrium and gas‐exchange formulas. Our results indicated that the water was consistently p CO 2 saturated (~90% of the cases) and that the steep terrain favors high gas evasion rates. The mean calculated fluvial export was 5.4 tC·km −2 ·year −1 with inorganic carbon dominating (dissolved inorganic carbon:dissolved organic carbon ratio >4), and degas rates (~40 tC km −2 ·year −1 ) were nearly sevenfold higher than the downstream export. The homogeneous land use in this nested catchment system results in similar water‐quality characteristics, and therefore, export rates are expected to be closely related to the rainfall–runoff relationships at each scale. Although the sampling campaigns did not fully reproduce storm‐event conditions and related effects such as flushing or dilution of in‐stream carbon, our results indicated a potential link between dissolved inorganic carbon and slower hydrological pathways related to subsurface water storage and movement.