Carbon Inputs From Riparian Vegetation Limit Oxidation of Physically Bound Organic Carbon Via Biochemical and Thermodynamic Processes

Graham, Emily B.; Tfaily, Malak M.; Crump, Alex R.; Goldman, Amy; Bramer, Lisa; Arntzen, Evan; Romero, Elvira; Resch, Charles T.; Kennedy, David W.; Stegen, James C.

doi:10.1002/2017jg003967

Cited by 60 publications

(81 citation statements)

References 74 publications

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“…While our results support previous field observations that emphasize the role of OM thermodynamics in predicting aerobic respiration 11,12 , we uniquely underscore the central role for OM thermodynamics in the metabolism of carbon-limited ecosystems using highly controlled laboratory experiments. A field study by Graham et al 11 showed that thermodynamically favorable OM was preferentially metabolized in sediments across a vegetation gradient. Similarly, Stegen et al 12 highlighted the importance of OM thermodynamics in regulating aerobic respiration within hyporheic zones.…”

Section: Thermodynamic Regulation Of Aerobic Respirationsupporting

confidence: 88%

“…This study was conducted using sediments from the Columbia River hyporheic zone within the Hanford Site 300 Area (approximately 46° 22’ 15.80”N, 119° 85 16’ 31.52”W) in eastern Washington, USA 10,11,45 . Hyporheic zone sediments were collected in April 2018 at five locations, separated by ~2 m (depth: ~30 cm).…”

Section: Methodsmentioning

confidence: 99%

“…To test the role OM chemistry as a key regulator of aerobic metabolism, we incubated sediments with thermodynamically distinct N-bearing or N-free OM treatments at concentrations commonly observed in freshwater systems (from 0.3 to 9 mg C L −1 , Supplementary Table 1) 12,24,25 . We inferred carbon limitation at low treatment concentrations (< 3 mg C L −1 ) because sediments were collected from a low carbon area (%C < 0.6 as previously discussed in Graham et al 11 ) with observed C:N < 5 11 which is typically associated with carbon limitation 26,27 . In addition, sediments were pre-processed prior to incubation until dissolved organic carbon concentrations were below instrument detection (see Methods and Supplementary Fig.…”

Section: Thermodynamic Regulation Of Aerobic Respirationmentioning

confidence: 99%

“…We provide direct evidence for OM thermodynamics in controlling aerobic respiration by demonstrating that thermodynamically-favorable OM supported enhanced respiration in microcosms under carbon limitation. We use the mean Gibbs free energy of the half reaction of organic carbon oxidation under standard conditions as a proxy for thermodynamic favorability throughout this paper, as per LaRowe and Van Cappellen 28 , Graham et al 11 , and Stegen et al 12 . Aerobic respiration was negatively correlated with when OM was amended at low concentrations (Fig.…”

Section: Thermodynamic Regulation Of Aerobic Respirationmentioning

confidence: 99%

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Carbon limitation leads to thermodynamic regulation of aerobic metabolism

Garayburu‐Caruso

Stegen

Song

et al. 2020

Preprint

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13Organic matter (OM) metabolism in freshwater ecosystems is a critical source of uncertainty in 14 global biogeochemical cycles, yet aquatic OM cycling remains poorly understood. Here, we 15 present the first work to explicitly test OM thermodynamics as a key regulator of aerobic 16 respiration, challenging long-held beliefs that organic carbon and oxygen concentrations are the 17 primary determinants of respiration rates. We pair controlled microcosm experiments with 18 ultrahigh-resolution OM characterization to demonstrate a clear relationship between OM 19 thermodynamic favorability and aerobic respiration under carbon limitation. We also 20 demonstrate a shift in the regulation of aerobic respiration from OM thermodynamics to nitrogen 21 content when carbon is in excess, highlighting a central role for OM thermodynamics in aquatic 22 biogeochemical cycling particularly in carbon-limited ecosystems. Our work therefore 23 illuminates a structural gap in aquatic biogeochemical models and presents a new paradigm in 24 which OM thermodynamics and nitrogen content interactively govern aerobic respiration. 25 26 27 3 Metabolism of organic matter (OM) in freshwater ecosystems plays a large role in global 28 biogeochemical cycles 1-3 , as freshwater ecosystems emit more than 2 Pg C yr -1 into the 29 atmosphere 4,5 . These emissions are largely dominated by contributions from river corridors 1,5,6 , 30 and within the river corridor, areas of groundwater-surface water mixing (hyporheic zones) have 31 a disproportionate impact on aerobic respiration 7-9 . Recent field observations have suggested that 32 OM chemistry, and in particular OM thermodynamics, are key to predicting aerobic respiration 33 in hyporheic zones 10-12 . If supported, these observations challenge a widespread paradigm that 34 organic carbon and oxygen concentrations are the primary determinants of aerobic respiration 35 rates and highlight a key source of model uncertainty. Yet, no work has provided direct evidence 36 for OM thermodynamics as a regulator of aerobic respiration in a controlled laboratory 37 environment. Demonstrating this behavior would identify mechanisms that drive field-based 38 phenomena and would enable key properties of OM to be represented in predictive models, 39 thereby contributing to reducing the uncertainty in modeling river corridor biogeochemical 40 cycling 13,14 . 41We use highly controlled aerobic microcosms, non-invasive dissolved oxygen consumption 42 rates, and ultrahigh-resolution OM characterization to investigate the role of OM chemistry in 43 determining aerobic respiration in hyporheic zone sediments. Based on field observations 10-12 , 44 we hypothesized that OM chemistry, including thermodynamic favorability and nitrogen (N) 45 content, would regulate aerobic respiration. Historically, investigations of thermodynamic 46 constraints on microbial metabolism have primarily focused on oxidation-reduction reactions 47 premise that using oxygen as the terminal electron acceptor provides sufficient energy ...

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Section: Thermodynamic Regulation Of Aerobic Respirationsupporting

confidence: 88%

Section: Methodsmentioning

confidence: 99%

Section: Thermodynamic Regulation Of Aerobic Respirationmentioning

confidence: 99%

Section: Thermodynamic Regulation Of Aerobic Respirationmentioning

confidence: 99%

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Carbon limitation leads to thermodynamic regulation of aerobic metabolism

Garayburu‐Caruso

Stegen

Song

et al. 2020

Preprint

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“…The river stage in the Columbia River is highly dynamic due to the upstream dam operations (Song et al, 2018). Geochemical and biogeochemical modeling for this system is subject to multiple uncertain factors, such as the permeability field controlled by geological formations and within-formation heterogeneity, river stage and river temperature dynamics under future climate scenarios, reaction network, and associated rates impacted by the abiotic environmental conditions as well as the microbial community that are present in the system (Graham et al, 2017;Stegen et al, 2016Stegen et al, , 2018. Therefore, sensitivity analysis is an essential step for better understanding the model system and implementing efficient strategies to reduce the uncertainty in model predictions.…”

Section: Implementation Of Groundwater Biogeochemical Reactive Transportmentioning

confidence: 99%

Using Bayesian Networks for Sensitivity Analysis of Complex Biogeochemical Models

Dai

Song

et al. 2019

Water Resources Research

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Sensitivity analysis is a vital tool in numerical modeling to identify important parameters and processes that contribute to the overall uncertainty in model outputs. We developed a new sensitivity analysis method to quantify the relative importance of uncertain model processes that contain multiple uncertain parameters. The method is based on the concepts of Bayesian networks (BNs) to account for complex hierarchical uncertainty structure of a model system. We derived a new set of sensitivity indices using the methodology of variance‐based global sensitivity analysis with the Bayesian inference. The framework is capable of representing the detailed uncertainty information of a complex model system using BNs and affords flexible grouping of different uncertain inputs given their characteristics and dependency structures. We have implemented the method on a real‐world biogeochemical model at the groundwater‐surface water interface within the Hanford Site's 300 Area. The uncertainty sources of the model were first grouped into forcing scenario and three different processes based on our understanding of the complex system. The sensitivity analysis results indicate that both the reactive transport and groundwater flow processes are important sources of uncertainty for carbon‐consumption predictions. Within the groundwater flow process, the structure of geological formations is more important than the permeability heterogeneity within a given geological formation. Our new sensitivity analysis framework based on BNs offers substantial flexibility for investigating the importance of combinations of interacting uncertainty sources in a hierarchical order, and it is expected to be applicable to a wide range of multiphysics models for complex systems.

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Geophysical mapping of hyporheic processes controlled by sedimentary architecture within compound bar deposits

McGarr

Wallace

Ntarlagiannis

et al. 2021

Hydrological Processes

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Hyporheic exchange influences water quality and controls numerous physical, chemical, and biological processes. Despite its importance, hyporheic exchange and the associated dynamics of solute mixing are often difficult to characterize due to spatial (e.g., sedimentary heterogeneity) and temporal (e.g., river stage fluctuation) variabilities. This study coupled geophysical techniques with physical and chemical sediment analyses to map sedimentary architecture and quantify its influence on hyporheic exchange dynamics within a compound bar deposit in a gravel-dominated river system in southwestern Ohio. Electromagnetic induction (EMI) was used to quantify variability in electrical conductivity within the compound bar. EMI informed locations of electrode placement for time-lapse electrical resistivity imaging (ERI) surveys, which were used to examine changes in electrical resistivity driven by hyporheic exchange. Both geophysical methods revealed a zone of high electrical conductivity in the center of the bar, identified as a fine-grained cross-bar channel fill. The zone acts as a baffle to flow, evidenced by stable electrical conditions measured by time-lapse ERI over the study period. Large changes in electrical resistivity throughout the survey period indicate preferential flowpaths through higher permeability sands and gravels. Grain size analyses confirmed sedimentological interpretations of geophysical data. Loss on ignition and x-ray fluorescence identified zones with higher organic matter content that are locations for potentially enhanced geochemical activity within the cross-bar channel fill. Differences in the physical and geochemical characteristics of cross-bar channel fills play an important role in hyporheic flow dynamics and nutrient processing within riverbed sediments. These findings enhance our understanding of the applications of geophysical methods in mapping riverbed heterogeneity and highlight the importance of accurately representing geomorphologic features and heterogeneity when studying hyporheic exchange processes.

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Carbon Inputs From Riparian Vegetation Limit Oxidation of Physically Bound Organic Carbon Via Biochemical and Thermodynamic Processes

Cited by 60 publications

References 74 publications

Carbon limitation leads to thermodynamic regulation of aerobic metabolism

Carbon limitation leads to thermodynamic regulation of aerobic metabolism

Using Bayesian Networks for Sensitivity Analysis of Complex Biogeochemical Models

Geophysical mapping of hyporheic processes controlled by sedimentary architecture within compound bar deposits

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