The role of terrestrially derived organic carbon in the coastal ocean: A changing paradigm and the priming effect

Bianchi, Thomas S.

doi:10.1073/pnas.1017982108

Cited by 659 publications

(518 citation statements)

References 110 publications

Supporting

Mentioning

500

Contrasting

Unclassified

Order By: Relevance

“…Combining this estimate with a global estimate by Meybeck (1982) that 40% of terrestrial organic matter enters the ocean as POC, and assuming that DOC is preferentially oxidised, yields a range for ocean POC oxidation of 44  19%. This is consistent with the estimate of Bianchi (2011) that 50% of terrestrial POC inputs are remineralised. Assigning arbitrary 25% ranges on values where uncertainties were not specified (reflecting also our reliance on data that were not specific to peat-derived POC in many cases), the combination of these yields an overall FracPOC-CO2 of 0.70, with a range of 0.49 to 0.91 (Figure 4).…”

Section: Contribution Of Peat Poc Fluxes To Co2 Emissionssupporting

confidence: 82%

“…For terrestrial DOC that does reach the ocean, it appears that (although specific values for peat-derived DOC are not available) most DOC is microbially processed, on a timescale of years to decades (e.g. Bianchi, 2011;Opsahl and Benner, 1997). Burdige (2005) estimated that sedimentation accounted for only around 15-30% of all (dissolved and particulate) terrestrial organic matter inputs to the ocean, with the remainder mineralised to CO2.…”

Section: Contribution Of Peat Doc Fluxes To Co2 Emissionsmentioning

confidence: 99%

See 1 more Smart Citation

The role of waterborne carbon in the greenhouse gas balance of drained and re-wetted peatlands

2015

View full text Add to dashboard Cite

Article (refereed) -postprintEvans, Chris D.; Renou-Wilson, Flo; Strack, Maria. 2016. The role of waterborne carbon in the greenhouse gas balance of drained and rewetted peatlands [in special issue: Carbon cycling in aquatic ecosystems] Aquatic Sciences, 78 (3). 573-590. 10.1007/s00027-015-0447-y Contact CEH NORA team at noraceh@ceh.ac.ukThe NERC and CEH trademarks and logos ('the Trademarks') are registered trademarks of NERC in the UK and other countries, and may not be used without the prior written consent of the Trademark owner.The role of waterborne carbon in the greenhouse gas balance of drained and re-wetted peatlands AbstractAccounting for greenhouse gas (GHG) emissions and removals in managed ecosystems has generally focused on direct land-atmosphere fluxes, but in peatlands a significant proportion of total carbon loss occurs via fluvial transport. This study considers the composition of this 'waterborne carbon' flux, its potential contribution to GHG emissions, and the extent to which it may change in response to land-management. The work describes, and builds on, a methodology to account for major components of these emissions developed for the 2013 Wetland Supplement of the Intergovernmental Panel on Climate Change. We identify two major components of GHG emissions from waterbodies draining organic soil: i) 'on site' emissions of methane (and to a lesser extent CO2) from drainage ditches located within the peatland; and ii) 'off site' emissions of CO2 resulting from downstream oxidation of dissolved and particulate organic carbon (DOC and POC) within the aquatic system. Methane emissions from ditches were found to be large in many cases (mean 60 g CH4 m -2 yr -1 based on all reported values), countering the view that methane emissions cease following wetland drainage. Emissions were greatest from ditches in intensive agricultural peatlands, but data were sparse and showed high variability. For DOC, the magnitude of the natural flux varied strongly with latitude, from 5 g C m -2 yr -1 in northern boreal peatlands to 60 g C m -2 yr -1 in tropical peatlands. Available data suggest that DOC fluxes increase by around 60% following drainage, and that this increase may be reversed in the longer-term through re-wetting, although variability between studies was high, especially in relation to re-wetting response. Evidence regarding the fate of DOC is complex and inconclusive, but overall suggests that the majority of DOC exported from peatlands is converted to CO2 through photo-and/or bio-degradation in rivers, standing waters and oceans. The contribution of POC export to GHG emissions is even more uncertain, but we estimate that over half of exported POC may eventually be converted to CO2. Although POC fluxes are normally small, they can become very large when bare peat surfaces are exposed to fluvial erosion. Overall, we estimate that waterborne carbon emissions may contribute about 1 to 4 t CO2-eq ha -1 yr -1 of additional GHG emissions from drained peatlands. For a number of worked examples this repres...

show abstract

Section: Contribution Of Peat Poc Fluxes To Co2 Emissionssupporting

confidence: 82%

Section: Contribution Of Peat Doc Fluxes To Co2 Emissionsmentioning

confidence: 99%

The role of waterborne carbon in the greenhouse gas balance of drained and re-wetted peatlands

2015

View full text Add to dashboard Cite

show abstract

“…A similar phenomenon, where the addition of labile carbon-stimulated decomposition of more recalcitrant carbon, described as 'priming', has been well documented in soils and marine systems, but has yet to be defined in the terrestrial subsurface (Bianchi, 2011). Priming can be caused by direct or indirect mechanisms (Kuzyakov et al, 2000); here we suggest the latter is more likely.…”

Section: Metabolic Interdependencies In An Aquifer Microbial Communitmentioning

confidence: 84%

Metabolic interdependencies between phylogenetically novel fermenters and respiratory organisms in an unconfined aquifer

et al. 2014

View full text Add to dashboard Cite

Fermentation-based metabolism is an important ecosystem function often associated with environments rich in organic carbon, such as wetlands, sewage sludge and the mammalian gut. The diversity of microorganisms and pathways involved in carbon and hydrogen cycling in sediments and aquifers and the impacts of these processes on other biogeochemical cycles remain poorly understood. Here we used metagenomics and proteomics to characterize microbial communities sampled from an aquifer adjacent to the Colorado River at Rifle, CO, USA, and document interlinked microbial roles in geochemical cycling. The organic carbon content in the aquifer was elevated via acetate amendment of the groundwater occurring over 2 successive years. Samples were collected at three time points, with the objective of extensive genome recovery to enable metabolic reconstruction of the community. Fermentative community members include organisms from a new phylum, Melainabacteria, most closely related to Cyanobacteria, phylogenetically novel members of the Chloroflexi and Bacteroidales, as well as candidate phyla genomes (OD1, BD1-5, SR1, WWE3, ACD58, TM6, PER and OP11). These organisms have the capacity to produce hydrogen, acetate, formate, ethanol, butyrate and lactate, activities supported by proteomic data. The diversity and expression of hydrogenases suggests the importance of hydrogen metabolism in the subsurface. Our proteogenomic data further indicate the consumption of fermentation intermediates by Proteobacteria can be coupled to nitrate, sulfate and iron reduction. Thus, fermentation carried out by previously unknown members of sediment microbial communities may be an important driver of nitrogen, hydrogen, sulfur, carbon and iron cycling.

show abstract

“…However, sediment organic matter (OM) is a complex and heterogeneous mixture of high-and low-molecular-weight organic carbon compounds derived from multiple sources (for example, marine or terrestrial) at different states of degradation. Generally, land-derived OM are thought to be more recalcitrant to degradation than plankton-derived OM (Hedges et al, 1997;Baldock et al, 2004), but in environments with a mixture of both kinds, different microbial groups can allow refractory OM to be metabolized through mutualistic relationships (Bianchi, 2011). Such relationships are, however, poorly understood as microbial communities are rarely investigated in the same context as OM source or OM quality, defined here as composition and lability.…”

Section: Introductionmentioning

confidence: 99%

River organic matter shapes microbial communities in the sediment of the Rhône prodelta

et al. 2014

View full text Add to dashboard Cite

Microbial-driven organic matter (OM) degradation is a cornerstone of benthic community functioning, but little is known about the relation between OM and community composition. Here we use Rhô ne prodelta sediments to test the hypothesis that OM quality and source are fundamental structuring factors for bacterial communities in benthic environments. Sampling was performed on four occasions corresponding to contrasting river-flow regimes, and bacterial communities from seven different depths were analyzed by pyrosequencing of 16S rRNA gene amplicons. The sediment matrix was characterized using over 20 environmental variables including bulk parameters (for example, total nitrogen, carbon, OM, porosity and particle size), as well as parameters describing the OM quality and source (for example, pigments, total lipids and amino acids and d 13 C), and molecular-level biomarkers like fatty acids. Our results show that the variance of the microbial community was best explained by d 13 C values, indicative of the OM source, and the proportion of saturated or polyunsaturated fatty acids, describing OM lability. These parameters were traced back to seasonal differences in the river flow, delivering OM of different quality and origin, and were directly associated with several frequent bacterial operational taxonomic units. However, the contextual parameters, which explained at most 17% of the variance, were not always the key for understanding the community assembly. Co-occurrence and phylogenetic diversity analysis indicated that bacteria-bacteria interactions were also significant. In conclusion, the drivers structuring the microbial community changed with time but remain closely linked with the river OM input.

show abstract

The role of terrestrially derived organic carbon in the coastal ocean: A changing paradigm and the priming effect

Cited by 659 publications

References 110 publications

The role of waterborne carbon in the greenhouse gas balance of drained and re-wetted peatlands

The role of waterborne carbon in the greenhouse gas balance of drained and re-wetted peatlands

Metabolic interdependencies between phylogenetically novel fermenters and respiratory organisms in an unconfined aquifer

River organic matter shapes microbial communities in the sediment of the Rhône prodelta

Contact Info

Product

Resources

About