What question did this study set out to answer?

The study aims to assess hydrological and metabolic factors influencing carbon export from a peatland in the Northern Andes.

May 29, 2026Open Access

Hydrologic connectivity with peatland soils drives very high carbon fluxes in a tropical, mountain stream

Puntos clave

The study aims to assess hydrological and metabolic factors influencing carbon export from a peatland in the Northern Andes.
Continuous monitoring of dissolved CO2, dissolved oxygen, and discharge at multiple stream locations.
Collection of discrete measurements for dissolved organic carbon and dissolved methane over several months.
Analysis of seasonal variations and hydrological impacts on carbon levels in stream ecosystems.
Highest recorded p CO2 levels in dry months (16,677 ± 3685 ppm) and lowest in wet months (5845 ± 2325 ppm).
Dissolved organic carbon concentrations increased with discharge, indicating hydrological influence on carbon export.
Significant anaerobic activity shown by high p CH4 levels (982 ± 797 ppm) at the peatland outlet.

Resumen

Abstract Inland waters receive large quantities of carbon from the surrounding landscape and are active sites of carbon transport, transformation, and emission. Global carbon emission estimates are limited by sparse and unevenly distributed carbon flux observations, particularly in the tropics. We evaluated hydrological and metabolic controls on carbon export variability from a large peatland in a tropical ecosystem typical of the Northern Andes mountains. We recorded dissolved CO 2 ( p CO 2 ), dissolved oxygen (DO), and discharge at 15-min intervals 5 m downstream of a peatland outlet (Station 1) and at 3 additional locations downstream (Stations 2, 3 and 4) from July 2019 until Jan 2020 and from June 2021 until March 2023. Continuous measurements of DO and discharge were also measured 2 km away in a stream draining an adjoining catchment (Station 5). Discrete measurements of dissolved organic carbon (DOC) and dissolved methane ( p CH 4 ) were collected in June-July of 2021 and 2022. Stream discharge was a primary control on p CO 2 and DOC in the stream network at both seasonal and event scales. DOC concentration increased with discharge and while p CO 2 decreased during higher flows, CO 2 loading increased. Pronounced seasonal changes were observed with lowest p CO 2 recorded at the peatland outlet in wet months (June–August: 5845 ± 2325 ppm, mean ± standard deviation), and the highest in dry months (Nov-Feb, 16,677 ± 3685 ppm). Anoxic or hypoxic conditions persisted for over half of our study and measurements of p CH 4 at the peatland outlet were very high (982 ± 797 ppm), underscoring the importance of anaerobic activity in this system. Aerobic processes also influenced p CO 2 dynamics. Aquatic metabolism at Station 5 (29 July–19 Oct 2021) was net heterotrophic, with ER exceeding GPP and net p CO 2 production (mean ER: − 6.5 g O 2 m −2 d −1 , GPP: 0.44 g O m −2 d −1 ). Our study highlights the role of hydrologic connectivity and diverse biogeochemical processes in shaping carbon export and cycling in páramo streams, which results in p CO 2 and p CH 4 levels among the highest reported in streams and rivers worldwide.

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