Abstract
Natural and human-induced controls on carbon dioxide (CO2) in tropical waters may be very dynamic (over time and among or within ecosystems) considering the potential role of warmer temperatures intensifying metabolic responses and playing a direct role on the balance between photosynthesis and respiration. The high magnitude of biological processes at low latitudes following eutrophication by nitrogen (N) and phosphorus (P) inputs into coastal lagoons waters may be a relevant component of the carbon cycle, showing controls on partial pressure of CO2 (pCO2) that are still poorly understood. Here we assessed the strength of N control on pCO2 in P-enriched humic and clear coastal lagoons waters, using four experimental treatments in microcosms: control (no additional nutrients) and three levels of N additions coupled to P enrichments. In humic coastal lagoons waters, a persistent CO2 supersaturation was reported in controls and all nutrient-enriched treatments, ranging from 24- to 4-fold the atmospheric equilibrium value. However, both humic and clear coastal lagoons waters only showed significant decreases in pCO2 in relation to the controlled microcosms in the two treatments with higher N addition levels. Additionally, clear coastal lagoons water microcosms showed a shift from CO2 sources to CO2 sinks, in relation to the atmosphere. Only in the two more N-enriched treatments did pCO2 substantially decrease, from 650 µatm in controls and less N-enriched treatments to 10 µatm in more N-enriched microcosms. Humic substrates and N inputs can modulate pCO2 even in P-enriched coastal lagoons waters, thereby being important drivers on CO2 outgassing from inland waters.
Highlights
Carbon dioxide (CO2) is one of most important greenhouse gas in terms of global warming (IPCC, 2007; Royer et al, 2007; Solomon et al, 2010)
High terrestrial organic inputs may explain the positive general trend reported between dissolved organic carbon (DOC) and the partial pressure of CO2 in lake waters (Jonsson et al, 2003)
Allochthonous organic resources contribute to high respiration rates and subsequently pressure of CO2 (pCO2) within most lake waters (Duarte and Prairie, 2005; Cole et al, 2007)
Summary
Carbon dioxide (CO2) is one of most important greenhouse gas in terms of global warming (IPCC, 2007; Royer et al, 2007; Solomon et al, 2010). Mean areal rates of CO2 evasion from lakes are higher at low latitudes, probably by the potential positive effect of warmer conditions on the organic decomposition (Marotta et al, 2009; Kosten et al, 2010). In this way, the degradation of organic matter to CO2 by bacteria shows important fluxes in the carbon cycling in natural aquatic ecosystems (Azam, 1998)
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