Dynamique des interactions biofilm/macro-organismes : conséquences sur les organismes et les propriétés hydrauliques et écologiques de l'interface eau/sédiment / Biofilm/macro-organisms interactions dynamic : consequences on the organisms and on the ecological and hydraulic properties of the water/sediment interface

Estragnat, Valerian

01 July 2019

Dans un contexte global d'augmentation de la population, les réserves en eau des nappes phréatiques sont de plus en plus sollicitées. Pour pallier à cette exploitation, des systèmes d’infiltration artificiels ont été mis en place pour recharger les nappes avec de l’eau de surface. Néanmoins, ces systèmes subissent des pertes d’efficacité liées au colmatage du support d’infiltration par des processus physiques, chimiques ou biologiques. Face à ce phénomène, le travail de thèse a pour but de tester la faisabilité d’une technique d’ingénierie écologique par introduction d’un gastéropode, V. viviparus, pour limiter le colmatage de l’interface eau/sédiment de bassins d’infiltration utilisés pour recharger artificiellement l’aquifère sous-jacent au Rhône. Par des approches expérimentales, deux volets ont été abordés, (1) la dynamique des interactions biofilm/brouteur et les conséquences sur l’état physiologique du gastéropode et (2) la dynamique des interactions biofilm/gastéropode et les conséquences sur les propriétés hydrauliques et écologiques de l’interface eau/sédiment. Les résultats ont mis en évidence que (1) V. viviparus pouvait se maintenir dans les bassins d’infiltration aux différentes saisons, (2) V. viviparus pouvait limiter le colmatage biologique de l’interface eau/sédiment soit par ses actions trophiques (broutage), soit par des actions physiques (déplacement, pelletisation) et (3) V. viviparus n’a pas eu d’effet positif sur l’infiltration lorsque le colmatage était chimique. Pour conclure, V. viviparus apparait comme un bon candidat pour des solutions d’ingénierie écologique visant à restaurer des interfaces eau/sédiment, colmatées par un biofilm phototrophe. Ce travail ouvre des perspectives sur l’utilisation de solutions basées sur la nature à plus large échelle spatiale (e.g. pilote) et à des milieux naturels comme les zones humides / With the global increase of the population, groundwater reserves are increasingly exploited. To circumvent this problem, managed aquifer recharge systems using surface water are used worldwide. Nevertheless, the hydraulic performance of these systems is often altered by physical, chemical or biological clogging. This work aim to test the sustainability of ecological engineering solution based on the introduction of the gastropod, V. viviparus, to attenuate the clogging of the water/sediment interface of infiltration basins use for the recharge of the Rhône river aquifer. Two sections have been addressed with experimental approaches, (1) dynamic of biofilm/grazer interaction and its consequences on the physiological state of the gastropod and (2) dynamic of biofilm/grazer interaction and its consequences on the hydraulic and ecological properties of the water/sediment interface. Results show that (1) V. viviparus is able to survive in the infiltration basins at contrasted seasons, (2) V. viviparus can attenuate the biological clogging of the water/sediment interface, ether by trophic interaction (grazing) or physical actions (crawling activity, pelletization), and (3) V. viviparus has no positive effect on infiltration in case of chemical clogging. To conclude, V. viviparus appears to be a good candidate for ecological engineering solutions aiming to preserve and restore water/sediment interface impacted by biological clogging. This work provides useful information for the study of natured based solutions at larger scale (experimental pilot) and in natural ecosystems as wetlands

Ingénierie écologique

Biomanipulation

Interface eau/sédiment

Recharge artificielle des aquifères

Colmatage

Biofilm phototrophe

Gastéropodes

Remaniement sédimentaire

Ecological engineering

Biomanipulation

Water/sediment interface

Managed aquifer recharge

Clogging

Phototrophic biofilm

Gastropods

Sediment reworking

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High Resolution Reconstruction of Rainfall Using Stable Isotopes in Growth Bands of Terrestrial Gastropod

Rangarajan, Ravi

January 2014

Reconstruction studies of seasonal rainfall utilizing stable isotope based proxy approach suffer from the limitations of time resolutions. Conventional methods and archives limit the achievable resolution to annual scales. However, high resolution reconstruction (seasonal to sub-weekly scale) can be achieved in proxy records where growth rates are high enough to leave spatial signatures in an organically or inorganically deposited layer such as growth bands. In this study, aragonitic skeleton of the gastropod Lissachatina fulica (Bowdich, Giant African Land Snails) is investigated with an aim to achieve sub-weekly scale reconstruction of the Indian monsoon rainfall. These terrestrial gastropods are native of Africa and highly invasive. Their evolution in the geological time period dates back to the Pliocene and is presently distributed across the tropical belt. They exhibit a high growth rate in the presence of water and high relative humidity in the environment. As a result, they are ideally suited for the task of palaeo seasonality reconstruction. The isotopic patterns recorded in their growth bands reveal composition of environmental water at seasonal time scales. In vitro studies were carried out on L. fulica to estimate their growth rates and growth responses to changes in the physical conditions within the culture chamber. The Indian monsoon rainfall exhibits characteristic dry spells that are generally sandwiched between periods of active phases of high rainfall during the South West monsoon season. These dry spells are typically characterized by rainfall with low intensity. Isotope fingerprinting of the rain water at daily time resolution, covering the years of 2007-10 exhibited distinct isotopic ratios for the dry and wet spells. Dry spells were clearly demarcated in the record with isotopically enriched signature. In addition, the study indentified the role of three distinct moisture sources on δ18O of rain water at Bangalore, India. The variability in the oxygen isotopic composition of the Indian monsoon rainfall is predominantly controlled by this source moisture variability at inter annual time scales, while temperature and amount of rainfall tend to dominate the variability in the precipitation isotopes at seasonal and weekly scales. Simultaneous isotopic analyses of both rainwater and shell carbonates growth bands were undertaken to understand their relationship to aid in high resolution reconstruction. Carbonate found in the growth bands of the gastropods, which is precipitated under equilibrium condition from rainwater, preserves the signature of rainfall. This provides an opportunity to reconstruct rainfall parameters (i.e. amount and moisture sources) knowing the variability in shell carbonates. Stable isotopic ratios measured across the growth bands of live shell specimens collected from the southern and eastern Indian regions (Bangalore and Kolkata, respectively) were compared with the rainfall isotope ratios at these two locations; signature of dry spells were clearly identified from the study of isotopic composition in the growth bands of the gastropod specimens. The approach was also extended to older samples from historical archives from eastern Indian region (Kolkata, East India). Individual specimens belonging to the same species of gastropod, which were collected during the monsoon season of the year 1918 were used for reconstructing the seasonal pattern in monsoon rainfall over the region. The record of variation in the isotopic composition seen in the shell was compared with the rainfall data from Indian Metrological Division observatory at Kolkata station. The year 1918 was characterized as a major drought year and the signature of dry period was seen preserved in the specimen. The work under taken in this thesis will widen the scope of seasonality reconstruction using terrestrial shell fossils from palaeo records, which have been rarely investigated in paleoclimate studies from the perspective of understanding the seasonal precipitation variability.

Rainfall Resconstruction

Rainwater

Carbonates

Indian Monsoon Rainfall

Palaeo Seasonality Reconstruction

Rain and Rainfall, Seasonal Variations

Terrestrial Gastropod

Stable Isotopes

High Resolution Rainfall Reconstruction

Terrestrial Gastropods

Lissachatina fulica

L. fulica

Bangalore Rainfall

stable Isotope Techniques

Meteorology

High Resolution Reconstruction of Rainfall Using Stable Isotopes in Growth Bands of Terrestrial Gastropod

Rangarajan, Ravi

January 2014

Reconstruction studies of seasonal rainfall utilizing stable isotope based proxy approach suffer from the limitations of time resolutions. Conventional methods and archives limit the achievable resolution to annual scales. However, high resolution reconstruction (seasonal to sub-weekly scale) can be achieved in proxy records where growth rates are high enough to leave spatial signatures in an organically or inorganically deposited layer such as growth bands. In this study, aragonitic skeleton of the gastropod Lissachatina fulica (Bowdich, Giant African Land Snails) is investigated with an aim to achieve sub-weekly scale reconstruction of the Indian monsoon rainfall. These terrestrial gastropods are native of Africa and highly invasive. Their evolution in the geological time period dates back to the Pliocene and is presently distributed across the tropical belt. They exhibit a high growth rate in the presence of water and high relative humidity in the environment. As a result, they are ideally suited for the task of palaeo seasonality reconstruction. The isotopic patterns recorded in their growth bands reveal composition of environmental water at seasonal time scales. In vitro studies were carried out on L. fulica to estimate their growth rates and growth responses to changes in the physical conditions within the culture chamber. The Indian monsoon rainfall exhibits characteristic dry spells that are generally sandwiched between periods of active phases of high rainfall during the South West monsoon season. These dry spells are typically characterized by rainfall with low intensity. Isotope fingerprinting of the rain water at daily time resolution, covering the years of 2007-10 exhibited distinct isotopic ratios for the dry and wet spells. Dry spells were clearly demarcated in the record with isotopically enriched signature. In addition, the study indentified the role of three distinct moisture sources on δ18O of rain water at Bangalore, India. The variability in the oxygen isotopic composition of the Indian monsoon rainfall is predominantly controlled by this source moisture variability at inter annual time scales, while temperature and amount of rainfall tend to dominate the variability in the precipitation isotopes at seasonal and weekly scales. Simultaneous isotopic analyses of both rainwater and shell carbonates growth bands were undertaken to understand their relationship to aid in high resolution reconstruction. Carbonate found in the growth bands of the gastropods, which is precipitated under equilibrium condition from rainwater, preserves the signature of rainfall. This provides an opportunity to reconstruct rainfall parameters (i.e. amount and moisture sources) knowing the variability in shell carbonates. Stable isotopic ratios measured across the growth bands of live shell specimens collected from the southern and eastern Indian regions (Bangalore and Kolkata, respectively) were compared with the rainfall isotope ratios at these two locations; signature of dry spells were clearly identified from the study of isotopic composition in the growth bands of the gastropod specimens. The approach was also extended to older samples from historical archives from eastern Indian region (Kolkata, East India). Individual specimens belonging to the same species of gastropod, which were collected during the monsoon season of the year 1918 were used for reconstructing the seasonal pattern in monsoon rainfall over the region. The record of variation in the isotopic composition seen in the shell was compared with the rainfall data from Indian Metrological Division observatory at Kolkata station. The year 1918 was characterized as a major drought year and the signature of dry period was seen preserved in the specimen. The work under taken in this thesis will widen the scope of seasonality reconstruction using terrestrial shell fossils from palaeo records, which have been rarely investigated in paleoclimate studies from the perspective of understanding the seasonal precipitation variability.

Rainfall Resconstruction

Rainwater

Carbonates

Indian Monsoon Rainfall

Palaeo Seasonality Reconstruction

Rain and Rainfall, Seasonal Variations

Terrestrial Gastropod

Stable Isotopes

High Resolution Rainfall Reconstruction

Terrestrial Gastropods

Lissachatina fulica

L. fulica

Bangalore Rainfall

stable Isotope Techniques

Meteorology