Carbon dioxide emissions from dry watercourses

Schiller, Daniel von; Marcé, Rafael; Obrador, Biel; Gómez‐Gener, Lluís; Casas-Ruiz, Joan Pere; Acuña, Vicenç; Koschorreck, Matthias

doi:10.5268/iw-4.4.746

Cited by 77 publications

(69 citation statements)

References 28 publications

(42 reference statements)

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“…On the contrary, in the absence of ephemeral vegetation, an increase in C release by dry watercourses is expected. This is in agreement with the data collected by Gallo et al (2014) and von Schiller et al (2014) who recorded summer release rates of CO 2 up to 371 mmol m -2 day -1 . Under the Mediterranean climate, the dry riverbeds should be considered active sites in terms of C emissions, with rates comparable to those from running waters (Gómez-Gener et al 2015).…”

Section: Introductionsupporting

confidence: 82%

“…In such a context, the contribution brought by periodically exposed saturated sediments (i.e. parafluvial zones) to the C metabolism and in particular the role of ephemeral vegetation as CO 2 traps, remains scarcely known (Gallo et al 2014;von Schiller et al 2014;Gómez-Gener et al 2015;Vidon et al 2016). Large subsurface flows in permeable river sediments may favour microbial conversion of dissolved organic C (DOC) into CO 2 , resulting in interstitial water supersaturation and large fluxes to the atmosphere.…”

Section: Introductionmentioning

confidence: 99%

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Role of ephemeral vegetation of emerging river bottoms in modulating CO2 exchanges across a temperate large lowland river stretch

et al. 2016

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Rivers and marginal wetlands contribute significantly to the carbon (C) exchange rate per unit area compared to adjacent terrestrial ecosystems, due to high C inputs, metabolic activity and CO 2 supersaturation. Within riverscapes, the contribution of emerging bottoms (i.e. parafluvial zones) and ephemeral vegetation (i.e. microphytobenthos or annual vascular plant communities) to the C metabolism is understudied. The aim of this study was to evaluate the CO 2 exchange rates at the water-and emergent sand bar-atmosphere interfaces within a lowland large temperate river stretch. CO 2 fluxes were measured seasonally, in summer (August 2007) and winter (March 2008) via static closed chambers, together with the primary producers' biomass (microphytobenthos and vascular macrophytes). Our results showed that the river was a CO 2 source (between 0.2 and 7.6 mmol CO 2 m -2 day -1 ), whilst the vegetated parafluvial zones acted as a net sink, with assimilation rates peaking at 623.4 mmol CO 2 m -2 day -1 . Emerging bare sediments were on the contrary net emitting CO 2 systems (2.7-60.1 mmol CO 2 m -2 day -1 ). Within lotic environments, seasonally emergent vegetated sand bars may represent important C fixation hot spots, with summer primary production particularly contributing to offsetting CO 2 emissions and counterbalancing the heterotrophic metabolism of the saturated zones. Based on these outcomes, we suggest that studies addressing the strictly aquatic fluvial environment, which is generally a CO 2 emitter, should be linked to those from transitional areas in order to better integrate terrestrial and aquatic C budgets.

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Section: Introductionsupporting

confidence: 82%

Section: Introductionmentioning

confidence: 99%

Role of ephemeral vegetation of emerging river bottoms in modulating CO2 exchanges across a temperate large lowland river stretch

et al. 2016

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“…A further expression of the high mineralization activity is that dry stream beds may become net exporters of CO 2 as occurs in dry soils do (von Schiller et al, 2014). These processes revert on the return of flow to the stream.…”

Section: The Relevance Of Temporary Streams In the Worldmentioning

confidence: 99%

Stream Biofilm Responses to Flow Intermittency: From Cells to Ecosystems

Sabater

Timoner

Borrego

et al. 2016

Front. Environ. Sci.

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Temporary streams are characterized by the alternation of dry and wet hydrological phases, creating both a harsh environment for the biota as well as a high diversity of opportunities for adaptation. These systems are mainly microbial-based during several of these hydrological phases, and those growing on all solid substrata (biofilms) accordingly change their physical structure and community composition. Biofilms experience large decreases in cell densities and biomass, both of bacteria and algae, during dryness. Algal and bacterial communities show remarkable decreases in their diversity, at least locally (at the habitat scale). Biofilms also respond with significant physiological plasticity to each of the hydrological changes. The decreasing humidity of the substrata through the drying process, and the changing quantity and quality of organic matter and nutrients available in the stream during that process, causes unequal responses on the biofilm bacteria and algae. Biofilm algae are affected faster than bacteria by the hydric stress, and as a result the ecosystem respiration resists longer than gross primary production to the increasing duration of flow intermittency. This response implies enhancing ecosystem heterotrophy, a pattern that can be exacerbated in temporary streams suffering of longer dry periods under global change.Keywords: biofilm, dry-rewetting cycle, temporary, intermittency, bacteria, algae, Mediterranean THE RELEVANCE OF TEMPORARY STREAMS IN THE WORLDFlow intermittency is part of the natural hydrology for streams and rivers, especially in arid and semi-arid landscapes. Temporary streams, or those that cease to flow at some points in space and time along their course, are a large fraction of many river networks, basically in tributaries of small order, but also in segments in the middle and lower parts of river networks. The number of temporary streams has been probably underestimated , as it appears from the application of novel on-site sensors, advances in remote sensing, and new modeling approaches. Flow intermittency has been estimated to account for 69% of first-order streams below 60 • , and up to 34% of larger order rivers (Raymond et al., 2013). Flow intermittency produces periodic or eventrelated loss of hydrologic connectivity between stream compartments, with consequences for all the processes ongoing in a waterway. Thus, flow intermittency triggers a chain of cascading effects eventually affecting water chemistry and biogeochemistry, as well as biodiversity, and ultimately community structure and ecosystem functioning.The direct implications of climate change and anomalous climatic events on flow regime are behind of the increasing temporality of many streams and rivers. Complex planetary scale processes, as well as local processes, may justify these situations. Anomalies such as the El Niño

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“…The difference in the flux becomes larger in downstream region, and 5 this difference is more predominant in the stream channel than in the hillslope. The simulated result implies the effect of river network data on carbon cycle variability, which is also related to the importance of dry watercourses, intermittent rivers, and temporary waterways (von Schiller et al, 2014). The other research also indicates the importance of dry rivers that they constitute more than 30 % of the total length and discharge of the global river network (Datry et al, 2014), and that 69 % of first-order streams below 60° latitude flow only intermittently (Raymond et al, 2013).…”

Section: Difference Of Hydrologic and Carbon Cycles Between Ob River mentioning

confidence: 88%

Biogeochemical contrast between different latitudes and the effect of human activity on spatio-temporal carbon cycle change in Asian river systems

Nakayama

2017

Preprint

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Abstract.Recent research has shown inland water may play some role in carbon cycling, although the extent of its contribution has remained uncertain due to limited amount of reliable data available. In this study, the author applied an advanced model coupling eco-hydrology and biogeochemical cycle (NICE-BGC) to regional-continental scales, which incorporates complex coupling of hydrologic-carbon cycle and interplay between inorganic and organic carbon. The author evaluates latitudinal 10 effect and human impact on hydrologic and carbon cycles between boreal Ob River, temperate Yangtze River, and subtropical Mekong River basins in Asia by using different resolutions of river network data. The model simulated more heterogenous distributions of water and carbon flux in the finer river network data in these regions, and helped to identify some hot spots on a regional scale. Then, the model was extended to continental scale at 1°x1° resolution with a time step of t = 1 day to evaluate seasonal and diurnal variations in carbon flux parameters. The model result showed there is a seasonal variability of horizontal 15 transport and vertical fluxes among boreal, temperate, and tropical regions and among each continent, which reflects seasonal variations of biologic and hydrologic processes there. The result showed CO2 evasion increases and sediment storage decreases in nighttime, particularly clearly seen temporarily in summer in Yangtze River, which implied some hot spots and hot moments in the day-night difference of vertical fluxes in regional scale. These results emphasize the important role of Asian river systems on global carbon cycle, and the further need to improve the resolution of simulation, to implement carbon observation network, 20 and to apply satellite data in the higher-resolution.

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Carbon dioxide emissions from dry watercourses

Cited by 77 publications

References 28 publications

Role of ephemeral vegetation of emerging river bottoms in modulating CO2 exchanges across a temperate large lowland river stretch

Role of ephemeral vegetation of emerging river bottoms in modulating CO2 exchanges across a temperate large lowland river stretch

Stream Biofilm Responses to Flow Intermittency: From Cells to Ecosystems

Biogeochemical contrast between different latitudes and the effect of human activity on spatio-temporal carbon cycle change in Asian river systems

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