Dissolved oxygen isotope modelling refines metabolic state estimates of stream ecosystems with different land use background

Piatka, David; Venkiteswaran, Jason J.; Uniyal, Bhumika; Kaule, Robin; Gilfedder, Benjamin; Barth, Johannes A. C.

doi:10.1038/s41598-022-13219-9

Cited by 7 publications

(7 citation statements)

References 88 publications

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“…Relative to concentrations at lower water levels, in-stream CO 2 was less affected by rainfall events than N 2 O and CH 4 due to anaerobic conditions in the peatland pore water, limiting microbial respiration (Drösler et al, 2008). However, the observed increase in CO 2 concentrations could be due to the input and oxidation of methane-rich peatland porewater, increasing DOC and TOC contents in the stream leached from the surrounding landscape as a C source for microbial turnover, and lower photosynthetic activities at lower PAR as compared to clear sky conditions (Figures 6E, 7B) (Dinsmore et al, 2013;Raymond et al, 2016;Piatka et al, 2021Piatka et al, , 2022bTaillardat et al, 2022). After reaching their maximum, significant decreases in GHG concentrations are probably related to reduced input of peatland soil water into the stream after the precipitation event or could be partially explained by dilution effects with rainwater and depletion of GHGs in the sediment pore waters (Hope et al, 2001;Billett et al, 2004;Wallin et al, 2010;Taillardat et al, 2022).…”

Section: Scientific Aspectsmentioning

confidence: 97%

“…Rocher-Ros et al, 2020;Attermeyer et al, 2021). During the day, when photosynthesis (P) (CO 2 sink and DO source) and respiration (R) (CO 2 source and DO sink) were active, CO 2 concentrations were lowest (but still above ambient concentrations), whereas the highest values were observed at night when only R is present (Hotchkiss et al, 2015;Piatka et al, 2021Piatka et al, , 2022b. With successive rainfall events, these diurnal CO 2 cycles were strongly dampened, likely by increased k values at higher water levels and flow velocities and possibly by reduced PAR, hence P under cloudy conditions (Figures 7A, B, E) (Raymond et al, 2012;Piatka et al, 2022b).…”

Section: Scientific Aspectsmentioning

confidence: 99%

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Precipitation fuels dissolved greenhouse gas (CO2, CH4, N2O) dynamics in a peatland-dominated headwater stream: results from a continuous monitoring setup

Piatka,

Nánási,

Mwanake

et al. 2024

Front. Water

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Stream ecosystems are actively involved in the biogeochemical cycling of carbon (C) and nitrogen (N) from terrestrial and aquatic sources. Streams hydrologically connected to peatland soils are suggested to receive significant quantities of particulate, dissolved, and gaseous C and N species, which directly enhance losses of greenhouse gases (GHGs), i.e., carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O), and fuel in-stream GHG production. However, riverine GHG concentrations and emissions are highly dynamic due to temporally and spatially variable hydrological, meteorological, and biogeochemical conditions. In this study, we present a complete GHG monitoring system in a peatland stream, which can continuously measure dissolved GHG concentrations and allows to infer gaseous fluxes between the stream and the atmosphere and discuss the results from March 31 to August 25 at variable hydrological conditions during a cool spring and warm summer period. Stream water was continuously pumped into a water-air equilibration chamber, with the equilibrated and actively dried gas phase being measured with two GHG analyzers for CO2 and N2O and CH4 based on Off-Axis Integrated Cavity Output Spectroscopy (OA-ICOS) and Non-Dispersive Infra-Red (NDIR) spectroscopy, respectively. GHG measurements were performed continuously with only shorter measurement interruptions, mostly following a regular maintenance program. The results showed strong dynamics of GHGs with hourly mean concentrations up to 9959.1, 1478.6, and 9.9 parts per million (ppm) and emissions up to 313.89, 1.17, and 0.40 mg C or N m−2h−1 for CO2, CH4, and N2O, respectively. Significantly higher GHG concentrations and emissions were observed shortly after intense precipitation events at increasing stream water levels, contributing 59% to the total GHG budget of 762.2 g m−2 CO2-equivalents (CO2-eq). The GHG data indicated a constantly strong terrestrial signal from peatland pore waters, with high concentrations of dissolved GHGs being flushed into the stream water after precipitation. During drier periods, CO2 and CH4 dynamics were strongly influenced by in-stream metabolism. Continuous and high-frequency GHG data are needed to assess short- and long-term dynamics in stream ecosystems and for improved source partitioning between in-situ and ex-situ production.

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Section: Scientific Aspectsmentioning

confidence: 97%

Section: Scientific Aspectsmentioning

confidence: 99%

Precipitation fuels dissolved greenhouse gas (CO2, CH4, N2O) dynamics in a peatland-dominated headwater stream: results from a continuous monitoring setup

Piatka,

Nánási,

Mwanake

et al. 2024

Front. Water

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“…Therefore DO is quickly consumed by biodegradation and slowly replenished by atmospheric oxygen due to slow hydrodynamic condition in the deltaic rivers. This means that the remaining DO is enriched in 18 O (Quay, et al, 1995;Piatka, et al, 2022). Next, nitrification in the NH4 + concentrated water (Trinh, et al, 2007) utilises the remaining DO within the hypoxic environment (Fig.…”

Section: Nitrification Denitrification and Biological Assimilationmentioning

confidence: 99%

“…In addition, in an aquatic ecosystem dominated by nitrification, the nitrate oxygen isotope ( 18 O of nitrate) in combination with the water oxygen isotope ( 18 O of H2O) can be used to calculate the dissolved oxygen isotope value. This oxygen isotope value can in turn be used to assess the aquatic metabolism (Venkiteswaran, et al, 2007;Piatka, et al, 2022). Here we apply nitrate isotopes and water isotopes to 1) assess the NO3sources and identify the processes governing NO3within stream water and 2) assess aquatic ecosystem metabolism within the Red River delta, which supports two of Vietnam's largest rivers, the Red River and the Day River (a significant tributary located in the heart of urban Vietnam) (Luu, et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Identifying the controls on nitrate and metabolic state within the Red River delta (Vietnam) with the use of stable isotopes

Smith,

Leng,

McGowan

et al. 2024

Journal of Hydrology

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“…Numerous studies have overcome this limitation by combining DO concentrations with stable oxygen isotopes (Levine et al, 2009;Mader et al, 2017;Li et al, 2019;Zhou et al, 2021;Piatka et al, 2022). The DO concentration, coupled with its oxygen isotopic composition, can provide additional information because it shows decoupling behaviors depending on oxygen sources and sink processes in the oxygen isotope and DO relationship (Levine et al, 2009;Zhou et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Oxygen isotopic fractionation during dissolved oxygen consumption in the bottom layer of the Ulleung Basin, East/Japan Sea

Kim,

Kang

2024

Front. Mar. Sci.

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The interpretation of decline in dissolved oxygen (DO) in the oxygenated bottom water of the Ulleung Basin (UB), southwest of the East/Japan Sea has been challenging because of the integrated influence of various DO-consuming processes. Therefore, the stable oxygen isotopic fractionation of DO was investigated to enhance our understanding of the distinct DO consumption observed in the bottom layers of the center of the UB. We explored the relationship between DO and its oxygen isotope composition (δ18ODO) using data collected at a station located in the center of the UB in 2020, 2021, and 2022. An unforeseen decrease in δ18ODO in the bottom layer (> 1800 m) where DO was depleted was discovered. The overall DO consumption in the mesopelagic water layer (300–1000 m), primarily attributed to water column respiration, exhibited an isotopic fractionation factor (α) with 0.985 ± 0.001 in the δ18ODO/[O2] relationship. The consumptive isotope fractionation factor in the bottom waters near the sediments (approximately 2146 m) showed a value slightly higher (0.988 ± 0.002) than that in the mesopelagic water layer. This isotopic signature is likely due to a smaller fractionation in the bottom waters relative to the mesopelagic water. The isotopic evidence suggests the involvement of mineral oxidation associated with excess dissolved Mn and Fe in the bottom waters because mineral oxidation exhibits a smaller fractionation effect than respiration. Our study demonstrates that DO depletion results from multiple consumption processes, including respiration, mineral oxidation, and diffusive transport, and the isotopic behavior provides evidence that mineral oxidation significantly influences DO consumption.

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Dissolved oxygen isotope modelling refines metabolic state estimates of stream ecosystems with different land use background

Cited by 7 publications

References 88 publications

Precipitation fuels dissolved greenhouse gas (CO2, CH4, N2O) dynamics in a peatland-dominated headwater stream: results from a continuous monitoring setup

Precipitation fuels dissolved greenhouse gas (CO2, CH4, N2O) dynamics in a peatland-dominated headwater stream: results from a continuous monitoring setup

Identifying the controls on nitrate and metabolic state within the Red River delta (Vietnam) with the use of stable isotopes

Oxygen isotopic fractionation during dissolved oxygen consumption in the bottom layer of the Ulleung Basin, East/Japan Sea

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