Oxygen saturation surrounding deep-water formation events in the Labrador Sea from Argo-O2 data

Wolf, Mitchell

04 August 2017

Deep-water formation supplies oxygen-rich water to the deep sea, spreading throughout the ocean via the global thermohaline circulation. Models suggest that gases in newly formed deep-water do not come to equilibrium with the atmosphere. However, direct measurements during wintertime convection are scarce, and the controls over the extent of this disequilibria are poorly quantified. Here we show that oxygen is consistently undersaturated at -6.3% to -7.6% in the Labrador Sea at the end of convection, when convection reaches deeper than 800 m. Deeper convection resulted in greater undersaturation while convection lasting later in the year resulted in values closer to equilibrium, from which we produce a predictive relationship. We use dissolved oxygen data from six profiling Argo floats in the Labrador Sea between 2003 to 2016, allowing direct observations of wintertime convection. Four of the six optode oxygen sensors displayed in situ drift of -2.98 μmol O2 kg-1 year-1 on average, which we corrected to stable deep-water oxygen values from repeat hydrography. Observations of low oxygen intrusions during restratification and a simple mixing calculation demonstrate that lateral processes act to lower the oxygen inventory of the central Labrador Sea. This suggests that the Labrador Sea is a net sink for atmospheric oxygen, but uncertainties in parameterizing gas exchange limit our ability to quantify the net uptake. Our results constrain the initial oxygen concentration of Labrador Sea Water and allow more precise estimates of oxygen utilization and nutrient regeneration in this water mass. / Graduate

Labrador Sea

dissolved oxygen

air-sea gas exchange

oxygen uptake

deep-water formation

deep convection

oxygen equilibrium

oxygen saturation

Zooplankton community structure and functioning in the North Western Mediterranean sea / Structure et fonctionnement des communautés zooplanctoniques de Méditerranée Nord-Occidentale

Donoso Ferez, Katty

11 July 2017

La Méditerranée Nord-Occidentale (MNO) est marquée par un processus de formation d’eau profonde en hiver qui induit une forte floraison phytoplanctonique au printemps. L'objectif de cette thèse a été de caractériser la dynamique de la communauté mesozooplanctonique à l'échelle régionale de la MNO, y compris dans la zone de convection profonde (ZCP), en évaluant ses stocks, sa composition taxonomique, sa structure en taille et ses liens trophiques avec le phytoplancton, en relation avec l'environnement hydro-biogéochimique. Trois campagnes océanographiques ont été menées en saisons contrastées: hiver, printemps et été, fournissant un jeu de données unique à cette échelle régionale. Le zooplancton est caractérisé par de faibles abondances et biomasses en hiver, surtout dans la ZCP, puis par une augmentation générale printanière, en abondance et en biomasse. Des différences spatiales s’observent, la ZCP présentant les plus forts changements de biomasse de l’hiver au printemps. Les valeurs d'été sont similaires aux valeurs hivernales et sont assez homogènes dans la zone d'étude. L'impact du broutage estimé n'est pas suffisant pour contrôler globalement la floraison printanière. Cependant, au printemps, toute la MNO, à l'exception de la ZCP, subit un contrôle top-down du zooplancton sur le phytoplancton, tandis que dans la ZCP, les valeurs de chlorophylle-a restent élevées malgré la forte demande en carbone du zooplancton, ce qui indique un contrôle bottom-up. Cette étude montre que la ZCP est probablement une zone d'intense transfert d'énergie vers les niveaux trophiques supérieurs ainsi que d'export de matière organique en MNO. / The North-Western Mediterranean Sea (NWMS) is characterized by a deep water convection process in winter, which induces a large phytoplankton bloom. The main objective of this thesis was to characterize the dynamics of the mesozooplankton community at the regional scale of NWMS including the deep convection zone (DCZ), by assessing its stocks, taxonomy and size structure, and by evaluating its phytoplankton-zooplankton trophic links in connection to the hydrological and biogeochemical environment. Three oceanographic cruises were conducted to map the NWMS in contrasting seasons: winter, spring, and summer. This represents a unique data set of zooplankton at this regional scale. The NWMS was characterized in winter by low zooplankton abundance and biomass. In spring, a general increase was found. Spatially DCZ was characterized by lowest stocks in winter and the highest in spring. In summer, biomass and abundance were similar to winter values and were quite homogenous over the study area. The estimated zooplankton grazing impact was not sufficient to globally control the spring phytoplankton bloom. However, in spring, all areas except the DCZ incurred top-down control by zooplankton on the phytoplankton stock. In the DCZ, the chlorophyll-a values remained high despite the high zooplankton biomass and carbon demand, indicating a sustained bottom-up control. This study indicates that the deep convection zone is likely an area of both enhanced energy transfer to higher trophic levels and organic matter export in NWMS.

Zooplancton

Transition hiver-Printemps

Situation estivale

Méditerranée Nord-Occidentale

Impact de la convection profonde

Relations phytoplancton –zooplancton

Zooplankton

North Western Mediterranean

Impact of deep water formation

Phytoplankton-Zooplankton interactions

Winter-Spring transition

Summer conditions

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