Spatial and temporal CO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; exchanges measured by Eddy Covariance over a temperate intertidal flat and their relationships to net ecosystem production

Polsenaere, Pierre; Lamaud, Éric; Lafon, Virginie; Bonnefond, Jean-Marc; Bretel, Patrice; Delille, Bruno; Deborde, Jonathan; Loustau, Denis; Abril, Gwénaël

doi:10.5194/bg-9-249-2012

Cited by 46 publications

(46 citation statements)

References 67 publications

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“…Efforts are also focused in using remote sensing reflectances from airbone hyperspectral data to assess MPB PP rates (Méléder et al, 2018). Recently, and in the light of the work of Brito et al (2013) Ibrom, Andreas and Rannik, Üllar and Moncrieff, John and Foken, Thomas and Kowalski, Andy S and Martin, Philippe H and Berbigier, Paul and Bernhofer, Ch and others, 1999;Zemmelink et al, 2009;Polsenaere et al, 2012). Similarly, the aquatic Biogeosciences Discuss., https://doi.org/10.5194/bg-2018-325 Manuscript under review for journal Biogeosciences Discussion started: 10 July 2018 c Author(s) 2018.…”

Section: Top-down Regulation Of Mpb Dynamics 30mentioning

confidence: 99%

“…The study of air-water and sediment-water exchanges through simultaneous atmospheric and aquatic EC measurements could 5 allow quantifying the importance of metabolic fluxes during immersion and emersion periods but also the coupled processes between the benthic and pelagic compartments such as MPB resuspension. Microphythobenthic community resuspension can significantly contribute to planktonic gross PP and, in turn, explain lower CO 2 fluxes from the water column to the atmosphere at high tide during the day than at night (Guarini et al, 2008;Polsenaere et al, 2012). To date, the modelling effort put on the physically-driven (tides and waves) resuspension processes of MPB is still limited (see Mariotti and Fagherazzi, 2012).…”

Section: Top-down Regulation Of Mpb Dynamics 30mentioning

confidence: 99%

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On biotic and abiotic drivers of the microphytobenthos seasonal cycle in a temperate intertidal mudflat: a modelling study

Savelli¹,

Dupuy²,

Barillé³

et al. 2018

Preprint

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Microphytobenthos (MPB) from intertidal mudflats are key primary producers at the land-ocean interface. MPB can be more productive than phytoplankton and sustain both benthic and pelagic higher trophic levels. The objective of this study is to assess the contribution of light, mud temperature, and gastropod Peringia ulvae grazing pressure in shaping the seasonal MPB dynamics on the Brouage mudflat (NW France). We use a physical-biological coupled model applied to the sediment 5 first centimeter for the year 2008. The simulated data compare to observations including time-coincident remotely sensed and in situ data. The model suggests a MPB annual cycle characterized by a main spring bloom, a biomass depression in summer, and a moderate fall bloom. In early spring, high simulated photosynthetic rates due to mud surface temperature (MST) values close to the MPB temperature optimum for photosynthesis and to increasing solar irradiance trigger the onset of the MPB spring bloom. After the bloom, high MST values lead to synoptic events when MPB thermo-inhibition (39.5 % of summer) 10 and limitation by P. ulvae grazing (8.7 % of summer) superimpose. During these synoptic events, 14 % of the simulated annual MPB primary production is channeled towards the P. ulvae secondary production through ingestion. The model suggests that such a combined effect is highly linked to the MPB biomass depression in summer. The model ability to infer on biotic and abiotic mechanisms driving the seasonal MPB dynamics could open the door to a new assessment of the export flux of biogenic matter at the land-ocean interface and, more generally, of the contribution of productive intertidal biofilms to the coastal carbon 15 cycle.At temperate latitudes, the seasonal cycle of MPB is shaped by the prevailing environmental conditions. Seasonal blooms are reported to occur throughout the year, i.e. in spring (De Jong and de Jonge, 1995;Sahan et al., 2007; Brito et al., 2013), summer (Cadée and Hegeman, 1977) and fall (Hubas et al., 2006;Garcia-Robledo et al., 2016). Along the French Atlantic coast, the spring bloom and summer depression observed in the Brouage mudflat in the Marennes-Oléron Bay are explained by optimal temperature conditions and thermo-inhibition, respectively (Blanchard et al., 1997). Reported differences in the 5 observed MPB seasonal cycles are also attributed to the diatom assemblage (Underwood, 1994). In terms of biomass, epipelic diatoms associated with muddy sediments show a higher seasonality caused by a marked exposure to stressful environmental conditions (e.g. cycle of deposition/erosion, dessication, grazing) than less motile epipsammic species buried in coarser sandy sediments (Underwood, 1994). In summer, thermo-inhibition and a high grazing pressure by deposit feeders are suggested to dampen the MPB biomass (Cadée and Hegeman, 1974; Cariou-Le Gall and Blanchard, 1995;Sahan et al., 2007). On intertidal 10 mudflats, the prosobranch gastropod Peringia ulvae can reach densities up to 30 000 snails m −2 (Sauriau et al.,...

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Section: Top-down Regulation Of Mpb Dynamics 30mentioning

confidence: 99%

Section: Top-down Regulation Of Mpb Dynamics 30mentioning

confidence: 99%

On biotic and abiotic drivers of the microphytobenthos seasonal cycle in a temperate intertidal mudflat: a modelling study

Savelli¹,

Dupuy²,

Barillé³

et al. 2018

Preprint

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“…Only very recently have researchers started to also extend eddy covariance measurements to ever more challenging and less widespread ecosystem types, such as mangroves Jha et al, 2014), deserts (Honrath et al, 2002;Liu et al, 2012;Li et al, 2014), intertidal flats (Polsenaere et al, 2012), and screenhouses (Tanny et al, 2006).…”

Section: Deployments In Different Ecosystem Typesmentioning

confidence: 99%

Eddy covariance for quantifying trace gas fluxes from soils

Eugster

Merbold

2015

SOIL

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Abstract. Soils are highly complex physical and biological systems, and hence measuring soil gas exchange fluxes with high accuracy and adequate spatial representativity remains a challenge. A technique which has become increasingly popular is the eddy covariance (EC) method. This method takes advantage of the fact that surface fluxes are mixed into the near-surface atmosphere via turbulence. As a consequence, measurements with an EC system can be done at some distance above the surface, providing accurate and spatially integrated flux density estimates. In this paper we provide a basic overview targeting scientists who are not familiar with the EC method. This review gives examples of successful deployments from a wide variety of ecosystems. The primary focus is on the three major greenhouse gases: carbon dioxide (CO 2 ), methane (CH 4 ), and nitrous oxide (N 2 O). Several limitations to the application of EC systems exist, requiring a careful experimental design, which we discuss in detail. Thereby we group these experiments into two main classes: (1) manipulative experiments, and (2) survey-type experiments. Recommendations and examples of successful studies using various approaches are given, including the combination of EC flux measurements with online measurements of stable isotopes. We conclude that EC should not be considered a substitute to traditional (e.g., chamber based) flux measurements but instead an addition to them. The greatest strength of EC measurements in soil science are (1) their uninterrupted continuous measurement of gas concentrations and fluxes that can also capture short-term bursts of fluxes that easily could be missed by other methods and (2) the spatial integration covering the ecosystem scale (several square meters to hectares), thereby integrating over small-scale heterogeneity in the soil.

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“…Therefore, the method has been widely used to estimate terrestrial atmospheric CO 2 fluxes (Lee et al, 2004). The method has also been used to estimate air-sea CO 2 fluxes in the ocean and coastal seas (McGillis et al, 2001;Vesala et al, 2006;Kondo & Tsukamoto, 2007;Zemmelink et al, 2009;Huotari et al, 2011;Polsenaere et al, 2012) and to estimate sediment-water O 2 fluxes (Berg et al, 2003;Kuwae et al, 2006). However, several studies have reported that results from the eddy covariance method are inconsistent with results from other methods, such as the bulk formula method (Kondo & Tsukamoto, 2007;Zemmelink et al, 2009).…”

Section: Air-sea Co 2 Fluxmentioning

confidence: 99%

Net uptake of atmospheric CO ₂ by coastal submerged aquatic vegetation

et al. 2014

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‘Blue Carbon’, which is carbon captured by marine living organisms, has recently been highlighted as a new option for climate change mitigation initiatives. In particular, coastal ecosystems have been recognized as significant carbon stocks because of their high burial rates and long-term sequestration of carbon. However, the direct contribution of Blue Carbon to the uptake of atmospheric CO2 through air-sea gas exchange remains unclear. We performed in situ measurements of carbon flows, including air-sea CO2 fluxes, dissolved inorganic carbon changes, net ecosystem production, and carbon burial rates in the boreal (Furen), temperate (Kurihama), and subtropical (Fukido) seagrass meadows of Japan from 2010 to 2013. In particular, the air-sea CO2 flux was measured using three methods: the bulk formula method, the floating chamber method, and the eddy covariance method. Our empirical results show that submerged autotrophic vegetation in shallow coastal waters can be functionally a sink for atmospheric CO2. This finding is contrary to the conventional perception that most near-shore ecosystems are sources of atmospheric CO2. The key factor determining whether or not coastal ecosystems directly decrease the concentration of atmospheric CO2 may be net ecosystem production. This study thus identifies a new ecosystem function of coastal vegetated systems; they are direct sinks of atmospheric CO2.

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Spatial and temporal CO<sub>2</sub> exchanges measured by Eddy Covariance over a temperate intertidal flat and their relationships to net ecosystem production

Cited by 46 publications

References 67 publications

On biotic and abiotic drivers of the microphytobenthos seasonal cycle in a temperate intertidal mudflat: a modelling study

On biotic and abiotic drivers of the microphytobenthos seasonal cycle in a temperate intertidal mudflat: a modelling study

Eddy covariance for quantifying trace gas fluxes from soils

Net uptake of atmospheric CO ₂ by coastal submerged aquatic vegetation

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Spatial and temporal CO&lt;sub&gt;2&lt;/sub&gt; exchanges measured by Eddy Covariance over a temperate intertidal flat and their relationships to net ecosystem production

Cited by 46 publications

References 67 publications

On biotic and abiotic drivers of the microphytobenthos seasonal cycle in a temperate intertidal mudflat: a modelling study

On biotic and abiotic drivers of the microphytobenthos seasonal cycle in a temperate intertidal mudflat: a modelling study

Eddy covariance for quantifying trace gas fluxes from soils

Net uptake of atmospheric CO 2 by coastal submerged aquatic vegetation

Contact Info

Product

Resources

About

Spatial and temporal CO<sub>2</sub> exchanges measured by Eddy Covariance over a temperate intertidal flat and their relationships to net ecosystem production

Net uptake of atmospheric CO ₂ by coastal submerged aquatic vegetation