Your search keyword '"Lecroart, Pascal"' showing total 8 results

1. Silicic acid flux to the ocean from tidal permeable sediments: A modeling study

Author

Chassagne, Romain Louis, Lecroart, Pascal, Beaugendre, Héloïse, Capo, Sylvain, Parisot, Jean-Paul, and Anschutz, Pierre

Subjects

*SILICIC acid, *TIDES, *SEDIMENTS, *GEOLOGICAL modeling, *SAND, *BEACHES, *ALGORITHMS, *SOIL permeability

Abstract

Abstract: Sandy sediments of tidal beaches are poor in reactive substances because they are regularly flushed by significant flow caused by tidal forcing. This transport process may significantly affect the flux of reactive solutes to the ocean. A two dimensional model coupling the Richards equation that describes the flow in permeable sediments and the conservation equation of the silicic acid was developed to simulate the evolution of the silicic acid concentration into a variably saturated porous media submitted to tidal forcing. A detailed algorithm of drainage zone under tidal forcing and numerical methods needed to solve it are properly presented. Flux to the ocean has been estimated. The silicic acid concentration displays a permanent lens with low silicic acid concentration at the top of the tidal zone. This lens that results from the tidal forcing, presents weak variations of area during the tidal cycle. Silicic outflux to the ocean increases with increasing beach slope, hydraulic conductivity and tidal range. Simulations reveal that the total silicic acid flux to the ocean from the coastal marine sands can be considered as significant compared to the flux supplied by the rivers. These results may alter the previously published global budget of the silicic acid to the ocean. [Copyright &y& Elsevier]

Published

2012

2. Carbon dynamics driven by seawater recirculation and groundwater discharge along a forest-dune-beach continuum of a high-energy meso-macro-tidal sandy coast.

Author

Charbonnier, Céline, Anschutz, Pierre, Abril, Gwenaël, Mucci, Alfonso, Deirmendjian, Loris, Poirier, Dominique, Bujan, Stéphane, and Lecroart, Pascal

Subjects

*SALTWATER encroachment, *BEACHES, *DISSOLVED organic matter, *COASTS, *GROUNDWATER, *BIOGEOCHEMICAL cycles, *SEAWATER

Abstract

High-energy tidal beaches are exposed to strong physical forcings. The submarine groundwater discharge (SGD) that occurs in intertidal sandy sediments includes both terrestrial, fresh groundwater flow and seawater recirculation, and plays a significant role in regulating biogeochemical cycles in some coastal zones. In this transition zone between land and sea, complex biogeochemical reactions alter the chemical composition of pore waters that discharge to the coastal ocean. Recent studies highlight that SGD can be a significant source of carbon to the coastal ocean but very few have investigated SGD in high-energy environments. We have characterized the dissolved carbon dynamics in such a high-energy environment (Truc Vert Beach, SW France) through pore-water sampling in key compartments of the SGD system. Dissolved organic carbon (DOC), pH, total alkalinity (TA), and the isotopic composition of dissolved inorganic carbon (δ13C-DIC) were measured in pore waters sampled at regular intervals between 2011 and 2014 in the intertidal zone of the beach, the mixing zone of the subterranean estuary (STE), and the freshwater aquifer upstream from the beach. Results reveal that SGD exports dissolved carbon mostly as DIC to the Aquitaine coast, some of which originates from the aerobic respiration of marine organic matter within the beach aquifer. This is highlighted by the reverse spatial trend of DOC, which is consumed, and DIC, which is produced. Saline pore waters expelled from the beach through tidally-driven recirculation of seawater provide about 4400 tons of carbon per year to the coastal zone of the 240-km long Aquitaine sandy coast. Terrestrial groundwater, characterized by high pCO 2 values, is also a significant contributor to the DIC flux to the coastal ocean (16,200 tons per year). This flux is abated by CO 2 evasion in the upper beach, at the onset of the salinity gradient in the STE, and within the surficial freshwater aquifer along the forest-beach transect below the coastal foredune. Accordingly, the DIC:TA ratio evolves to below 1, suggesting that this SGD increases the buffer capacity of coastal seawater against acidification. This study demonstrates that high-energy beaches are active vectors of DIC from the land to the coastal ocean as well as significant sources of CO 2 to the atmosphere, and must therefore be taken into consideration in SGD carbon budgets. [ABSTRACT FROM AUTHOR]

Published

2022

3. Biogeochemistry in an intertidal pocket beach.

Author

Mouret, Aurélia, Charbonnier, Céline, Lecroart, Pascal, Metzger, Edouard, Howa, Hélène, Deflandre, Bruno, Deirmendjian, Loris, and Anschutz, Pierre

Subjects

*MARINE debris, *BEACHES, *PORE water, *DISSOLVED oxygen in water, *WATER waves, *WAVE energy, *BIOGEOCHEMISTRY

Abstract

Sandy beaches are places of active organic matter mineralization due to water renewal providing organic matter and electron acceptors in the porous and permeable sands. Recycled biogenic compounds are efficiently transferred to the coastal marine environment via wave and tidal-driven advective flows. The biogeochemical processes in beach aquifers were mainly studied in semi enclosed systems with low tidal amplitude, and with a connection to continental aquifers contributing to solute fluxes to the coast from terrestrial groundwater. We present here the study of a pocket beach isolated from terrestrial aquifers with a high tidal amplitude and a medium energy wave regime. In situ measurements, cross-shore profiles and vertical sampling were conducted during several tidal cycles in spring and autumn. Cross-shore transects, obtained at low tide from holes that represent a mixture of the upper 20 cm of the water saturated zone, showed concentration gradients of redox and recycled compounds. Increase in pCO 2 , dissolved phosphate and ammonium concentrations downslope revealed that more products from organic matter mineralization accumulated in the lower beach. The related increase in total alkalinity downslope indicated that the part of anaerobic processes in organic matter oxidation was higher in the lower beach. Concentration and δ13C of dissolved inorganic carbon in pore waters suggested that the carbon mineralized in pore waters came from marine plant debris that were mixed with the sand. Continuous probe records of dissolved oxygen saturation and vertical profiles revealed a tidally-driven dynamics of pore water in the first centimetres of the lower beach aquifer. Ventilation of pore waters corresponded to wave pumping and swash-induced infiltration of seawater in the upper 10–20 cm of sediment. Nutrients and reduced compounds produced through organic matter mineralization remained stored in pore water below the layer disturbed by wave. The flux of these components to seawater is possible when this interface is eroded, for example when wave energy increases after a less energetic period. The low extension of the studied aquifer, typical of pocket beaches, limits the connection with continental groundwater. Both tidally-driven and wave-driven recirculation of seawater allows pocket beaches to be efficient bioreactors for marine organic matter mineralization. As such, they provide the coastal environment with recycled nutrients, and not new nutrients. • SGD and early diagenesis in a high tidal amplitude pocket beach. • We observed a vertical and a horizontal redox gradient in the beach aquifer. • Tidally and wave-driven seawater recirculation promotes organic matter mineralization. • Recycled nutrients and alkalinity fluxes to the coastal ocean. • Labile organic matter originates from marine plant debris. [ABSTRACT FROM AUTHOR]

Published

2020

4. Measuring pore water oxygen of a high-energy beach using buried probes.

Author

Charbonnier, Céline, Anschutz, Pierre, Deflandre, Bruno, Bujan, Stéphane, and Lecroart, Pascal

Subjects

*PORE water, *DISSOLVED oxygen in water, *BEACHES, *AQUIFERS, *INTERTIDAL ecology, *SALINE waters

Abstract

We conducted six field campaigns to investigate the spatial and temporal evolution of pore water oxygen content on a high-energy sandy beach aquifer during several tidal cycles at different seasons. We buried autonomous probes in intertidal sands to record dissolved oxygen saturation, salinity, temperature and water head at a 2–10 min frequency. Oxygen concentrations display significant changes both with time (tide and seasons) and space (cross-shore and vertical variations). Seawater circulation in tidal sands forms a saline pore water circulation cell with oxygen-saturated pore water in the zone of seawater recharge. Oxygen-depleted pore water in the lower beach is the result of in situ respiration processes that occur during seawater circulation. Oxygen depletion varies throughout the year and anoxic conditions are reached at the end of spring, as planktonic organic matter becomes abundant in seawater and more organic matter is therefore supplied to pore water. On a shorter time scale (weeks to minutes), oxygen variations are driven directly by physical forcing. Tidal amplitude affects the extent of the saltwater circulation cell and the associated location of the recharging and discharging zones of the beach. The evolution of the water table level during the tidal cycle influences the circulation of pore water in the sand and ultimately, the timing of oxygen variations during flood and ebb. This first in situ study in a high-energy sandy beach shows that the dynamics of pore water oxygen are governed by biogeochemical processes at the seasonal scale and by physical forcing at the time scale of minutes to a few days. [ABSTRACT FROM AUTHOR]

Published

2016

5. Shape of the shallow aquifer at the fresh water–sea water interface on a high-energy sandy beach.

Author

Buquet, Damien, Sirieix, Colette, Anschutz, Pierre, Malaurent, Philippe, Charbonnier, Céline, Naessens, Fabien, Bujan, Stéphane, and Lecroart, Pascal

Subjects

*AQUIFERS, *BEACHES, *COASTAL sediments, *ESTUARIES, *COASTS, *FRESH water, *SEAWATER, *SALINITY

Abstract

Inland aquifers are connected to the ocean through permeable coastal sediments. The mixing zone between sea water and fresh-groundwater forms a so-called subterranean estuary. The dynamics and the shape of this interface influence fluxes of fresh water to the coastal zone. On tidal sandy beaches, tide and waves actions lead to the formation of an intertidal saline circulation cell that complements the structure of the subterranean estuary between sea water and fresh water. The upper beach corresponds to the recharge zone, where large volumes sea water penetrate the sediment at high tide, whereas the lower beach corresponds to the discharge zone of older pore water that remains in the sand for several tidal cycles. The objective of our study was to characterize the shape and the evolution of this saline cell in a high-energy macro-tidal beach, the Truc Vert beach (SW France). In order to assess the distribution of saline, brackish and fresh water in this high-energy beach aquifer, we conducted electrical resistivity tomography (ERT) measurements from the lower beach face to the sand dune in winter 2012–2013. We also measured water table elevation and salinity in three piezometers situated at the base of the dune and in pore waters at low tide on tidal cross-shore transects. Results show that the intertidal saline plume can be identified and localized with the ERT method. The fresh-saline water interface is almost vertical in the upper beach. The saline circulation cell occupies the upper part of the tidal beach over a thickness of 5 m deep. Below this saline cell, a brackish water flows to the ocean: about 30% of fresh water was found in pore water in the lower part of the beach. Shifting of the vertical front between saline and fresh waters of about 2–5 m occurred during the spring–neap tidal cycle. This migration is small relative to the beach size, suggesting that the transition zone is relatively stable. The variations in salinity of the circulation cell suggest that the position of the saline plume is controlled by the spring tide level. Our results differ slightly from studies based on modelling and piezometric measurement made in less exposed micro-tidal sandy beaches. Our data would allow to better constrain numerical models that would enable to quantify water residence time and solute fluxes in subterranean estuaries of high-energy beaches. [ABSTRACT FROM AUTHOR]

Published

2016

6. Role of macrofauna on benthic oxygen consumption in sandy sediments of a high-energy tidal beach.

Author

Charbonnier, Céline, Lavesque, Nicolas, Anschutz, Pierre, Bachelet, Guy, and Lecroart, Pascal

Subjects

*MARINE sediments, *BEACHES, *TIDES, *BIOGEOCHEMISTRY, *MICROBIAL respiration

Abstract

Sandy beaches exposed to tide and waves are characterized by low abundance and diversity of benthic macrofauna, because of high-energy conditions. This is the reason why there are few studies on benthic communities living in such highly dynamic environments. It has been shown recently that tidal sandy beaches may act as biogeochemical reactors. Marine organic matter that is supplied in the sand during each flood tide is efficiently mineralized through aerobic respiration. In order to quantify the role of macrofauna in the whole beach benthic respiration, we studied the macrofauna and the pore water oxygen content of an exposed sandy beach (Truc Vert, SW of France) during four seasons in 2011. The results showed that macrofauna was characterised by a low number of species of specialized organisms such as the crustaceans Eurydice naylori and Gastrosaccus spp. and the polychaetes Ophelia bicornis and Scolelepis squamata . The distribution and abundance of macrofauna were clearly affected by exposure degree and emersion time. The combined monitoring of benthic macrofauna and pore waters chemistry allowed us to estimate (1) the macrofauna oxygen uptake, calculated with a standard allometric relationship using biomass data, and (2) the total benthic oxygen uptake, calculated from the oxygen deficit measured in pore waters. This revealed that benthic macrofauna respiration represented a variable but low (<10%) contribution to the total benthic oxygen consumption. This suggests that oxygen was mainly consumed by microbial respiration. [ABSTRACT FROM AUTHOR]

Published

2016

7. Aerobic respiration in a high-energy sandy beach.

Author

Charbonnier, Céline, Anschutz, Pierre, Poirier, Dominique, Bujan, Stéphane, and Lecroart, Pascal

Subjects

*CARBON content of seawater, *BEACHES, *MARINE sediments, *OXYGEN content of seawater, *DISSOLVED oxygen in water

Abstract

Abstract: Wave and tide dominated beaches are composed of medium to coarse sandy sediments depleted in organic matter. In these sediments, the availability of organic matter limits benthic heterotrophic respiration processes. This study shows that oxygen consumption linked with nutrient recycling occurs in sands and that the intensity of this process follows a seasonal pattern. Furthermore, substantial seawater exchange occurs through intertidal sandy sediments during each tide. During floods, seawater penetrates sandy sediments, filling the pore spaces with dissolved oxygen and marine organic matter. Water expelled from the sediment during ebb is depleted in oxygen and enriched in nitrate. In order to quantify the extent of respiration processes, we collected pore waters at low tide on tidal cross-shore transects on the Truc Vert beach (France) every two weeks over 20months. Temperature, salinity and oxygen saturation were recorded in situ and nutrient concentrations were determined from collected samples. The seasonal monitoring showed that aerobic respiration occurred in sands. Organic matter supplied by the seawater entering the pore spaces during floods was trapped long enough to be mineralized. An efficient recycling of nutrients was thus found to occur in tidal sandy beaches. The intensity of the respiration processes varied seasonally. The strongest oxygen depletions occurred in spring, when planktonic organic matter was abundant, as well as in summer when we observed occasional denitrification. Nitrate concentration of recycled seeping seawater reached values up to 40μM. According to our calculations, the 240-km-long Aquitanian beach recycles 3500t of carbon and releases 600t of N-nitrate to the adjacent coastal zone each year. Since phosphorus is readily adsorbed on particles, the N:P ratio of recycled nutrients released to the seawater was much higher than the Redfield ratio. [Copyright &y& Elsevier]

Published

2013

8. Tidal sands as biogeochemical reactors

Author

Anschutz, Pierre, Smith, Thomas, Mouret, Aurélia, Deborde, Jonathan, Bujan, Stéphane, Poirier, Dominique, and Lecroart, Pascal

Subjects

*SAND, *TIDES, *CHEMICAL reactors, *BIOGEOCHEMISTRY, *SEDIMENTS, *BEACHES, *ORGANIC compounds, *PORE water, *SALINITY, *WATER temperature

Abstract

Abstract: Sandy sediments of continental shelves and most beaches are often thought of as geochemical deserts because they are usually poor in organic matter and other reactive substances. The present study focuses on analyses of dissolved biogenic compounds of surface seawater and pore waters of Aquitanian coastal beach sediments. To quantitatively assess the biogeochemical reactions, we collected pore waters at low tide on tidal cross-shore transects unaffected by freshwater inputs. We recorded temperature, salinity, oxygen saturation state, and nutrient concentrations. These parameters were compared to the values recorded in the seawater entering the interstitial environment during floods. Cross-shore topography and position of piezometric level at low tide were obtained from kinematics GPS records. Residence time of pore waters was estimated by a tracer approach, using dissolved silica concentration and kinetics estimate of quartz dissolution with seawater. Kinetics parameters were based on dissolved silica concentration monitoring during 20-day incubations of sediment with seawater. We found that seawater that entered the sediment during flood tides remained up to seven tidal cycles within the interstitial environment. Oxygen saturation of seawater was close to 100%, whereas it was as low as 80% in pore waters. Concentrations of dissolved nutrients were higher in pore waters than in seawater. These results suggest that aerobic respiration occurred in the sands. We propose that mineralised organic matter originated from planktonic material that infiltrated the sediment with water during flood tides. Therefore, the sandy tidal sediment of the Aquitanian coast is a biogeochemical reactor that promotes or accelerates remineralisation of coastal pelagic primary production. Mass balance calculations suggest that this single process supplies about 37kmol of nitrate and 1.9kmol of dissolved inorganic phosphorus (DIP) to the 250-km long Aquitanian coast during each semi-diurnal tidal cycle. It represents about 1.5% of nitrate and 5% of DIP supplied by the nearest estuary. [Copyright &y& Elsevier]

Published

2009