Partitioning carbon sources between wetland and well-drained ecosystems to a tropical first-order stream – implications for carbon cycling at the watershed scale (Nyong, Cameroon)

Abstract: Abstract. Tropical rivers emit large amounts of carbon dioxide (CO2) to the atmosphere, in particular due to large wetland-to-river carbon (C) inputs. Yet, tropical African rivers remain largely understudied, and little is known about the partitioning of C sources between wetland and well-drained ecosystems to rivers. In a first-order sub-catchment (0.6 km2) of the Nyong watershed (Cameroon 27 800 km2), we fortnightly measured C in all forms and ancillary parameters in groundwater in a well-drained forest (her… Show more

“…Potential contribution of NEP to CO 2 evasion in different streams and rivers, extracted from Abril et al (2014), Bernal et al (2022), Borges et al (2019), Borges et al (2015), Carter et al (2022), Cole and Caraco (2001), Demars (2019), Duvert et al (2019); Ellis et al (2012), Gómez‐Gener et al (2016), Hotchkiss et al (2015), Lupon et al (2019), Lynch et al (2010), Marzolf et al (2022), Moustapha et al (2022), Rasilo et al (2017), Rocher‐Ros et al (2020), Taillardat et al (2022), Teodoru et al (2015), Wang et al (2021), and Winterdahl et al (2016). 1 Estimates for 2005.…”

“…5). External CO 2 sources in this case may have comprised soil water and groundwater inputs of terrestrially derived CO 2 (Johnson et al 2008; Duvert et al 2018), a pathway that can be facilitated by the high connectivity between wetland soils, riparian areas and the stream network at high flow (Birkel et al 2020; Moustapha et al 2022). Given the concomitantly high internal CO 2 production via NEP during the early storms and wet season (Fig.…”

“…Marzolf et al (2022) found that 16% of the CO 2 evasion from a small, steep stream in Costa Rica can be sourced from stream metabolism, similar in magnitude to groundwater and upstream inputs of CO 2 . In tropical Africa, estimations by Borges et al (2015), Borges et al (2019), Moustapha et al (2022), andTeodoru et al (2015) indicate that stream metabolism contributes little CO 2 to the evasion flux, with contributions ranging from 0% to 33% in individual rivers, and 14% at a continental scale. Overall, these studies illustrate the huge variability in processes across river orders and morphologies and suggest that more work is needed to better understand and quantify the key controls on these fluxes for different tropical climates and landscapes.…”

Stream respiration exceeds CO₂ evasion in a low‐energy, oligotrophic tropical stream

“…Potential contribution of NEP to CO 2 evasion in different streams and rivers, extracted from Abril et al (2014), Bernal et al (2022), Borges et al (2019), Borges et al (2015), Carter et al (2022), Cole and Caraco (2001), Demars (2019), Duvert et al (2019); Ellis et al (2012), Gómez‐Gener et al (2016), Hotchkiss et al (2015), Lupon et al (2019), Lynch et al (2010), Marzolf et al (2022), Moustapha et al (2022), Rasilo et al (2017), Rocher‐Ros et al (2020), Taillardat et al (2022), Teodoru et al (2015), Wang et al (2021), and Winterdahl et al (2016). 1 Estimates for 2005.…”

“…5). External CO 2 sources in this case may have comprised soil water and groundwater inputs of terrestrially derived CO 2 (Johnson et al 2008; Duvert et al 2018), a pathway that can be facilitated by the high connectivity between wetland soils, riparian areas and the stream network at high flow (Birkel et al 2020; Moustapha et al 2022). Given the concomitantly high internal CO 2 production via NEP during the early storms and wet season (Fig.…”

“…Marzolf et al (2022) found that 16% of the CO 2 evasion from a small, steep stream in Costa Rica can be sourced from stream metabolism, similar in magnitude to groundwater and upstream inputs of CO 2 . In tropical Africa, estimations by Borges et al (2015), Borges et al (2019), Moustapha et al (2022), andTeodoru et al (2015) indicate that stream metabolism contributes little CO 2 to the evasion flux, with contributions ranging from 0% to 33% in individual rivers, and 14% at a continental scale. Overall, these studies illustrate the huge variability in processes across river orders and morphologies and suggest that more work is needed to better understand and quantify the key controls on these fluxes for different tropical climates and landscapes.…”

Stream respiration exceeds CO₂ evasion in a low‐energy, oligotrophic tropical stream

“…In addition, wetland, known as a reliable C source for rivers (Abril & Borges, 2019), accounts for less than 1% of the total area of the ERB (Figure S5 in Supporting Information ). Therefore, a considerable proportion of terrestrial C could not be converted into a more labile form in wetlands before entering the river network (Algesten et al., 2004; Moustapha et al., 2021), restricting the in‐stream decomposition of terrestrial C.…”

Basin‐Scale CO₂ Emissions From the East River in South China: Importance of Small Rivers, Human Impacts and Monsoons

“…This suggests that wetlands, when hydrologically connected to streams, act as steady sources of GHGs. The paramount importance of lateral carbon inputs from wetlands to explain GHGs emissions from streams was also reported in Africa, such as the Congo River network (Borges et al, 2019) and the Nyong watershed (Moustapha et al, 2022), high altitude tropical wetlands (Schneider et al, 2020), but also in temperate and boreal peatlands (Billett & Harvey, 2013;Billett & Moore, 2008;Dinsmore et al, 2010). Considering the relatively flat topographies draining wetlands and the large carbon stocks they hold, particularly in peatlands, it is worth exploring their carbon GHG dynamics and identifying their biogeochemical specificities, in comparison to other headwater streams.…”

Carbon Dioxide and Methane Dynamics in a Peatland Headwater Stream: Origins, Processes and Implications