Variability and trends in the tropical Pacific and the El Niño-Southern Oscillation inferred from coral and lake archives

Thompson, Diane Marie

January 2013

The background state and changes associated with the El Niño-Southern Oscillation (ENSO) in the tropical Pacific Ocean influence climate patterns all over the world. Understanding how the tropical Pacific will be impacted by climate change is therefore critical to accurate regional climate projections. However, sparse historical data coverage and strong natural variability in the basin make it difficult to assess the response of the tropical Pacific to anthropogenic climate change. Further, climate models disagree regarding the response of the basin to continued anthropogenic forcing into the future. Building off of the limited instrumental record, high-resolution records from coral and lake sediment archives can be used to assess the response of the tropical Pacific to past climate changes and to compare and assess climate model projections. In the present study, I use high-resolution coral and lake records from the equatorial Pacific to assess climate model projections and the response of the coupled ocean-atmospheric climate system in the basin (ocean temperature, salinity, winds, precipitation) to natural and anthropogenic forcing. Using a simple model of how climate is recorded by corals, we compare historical climate data and climate model simulations with coral paleoclimate records to assess climate model projections and address uncertainties in the historical data, models and paleoclimate records. We demonstrate that this simple model is able to capture variability and trend observed in the coral records, and show that the both sea surface temperature and salinity contribute to the observed coral trend. However, we find major discrepancies in the observed and climate model simulated trends in the tropical Pacific that may be attributed to uncertainties in model simulated salinity. We then assess 20th-century variability and trends in SST and salinity in the central tropical Pacific using replicated coral δ¹⁸O and Sr/Ca records from the Republic of Kiribati and the central Line Islands. We find that the coral records from these sites display a warming and freshening trend superimposed on strong interannual and low-frequency variability. Further, we demonstrate an apparent strengthening of the E-W SST gradient across the dateline (between 173°E and 160°W) and a slight weakening of the N-S SST gradient due to enhanced warming along the equator and west of the dateline relative to other sites. However, we find no evidence of increased variability in the central Pacific, suggesting that there has not been an increase in central Pacific style ENSO events. Finally, we show that the salinity response to climate change may be very patchy within the basin. Using a new ~90 year coral Mn/Ca record from the central Pacific, we investigate variability and trends in tropical Pacific trade winds. First, we demonstrate a strong association between westerly wind anomalies and coral skeletal Mn/Ca, which recorded all of the major historical El Niño events of the 20th century. In this new long Mn/Ca record, we find a reduction in the amplitude and frequency of Mn/Ca pulses between 1893 and 1982, suggesting a decrease in westerly wind anomalies in the western equatorial Pacific Ocean. Finally, we use a sediment record from Bainbridge Crater Lake, Galápagos Archipelago to assess variability in the eastern tropical Pacific over the past ~6 thousand years. Based on results from long-term monitoring of the lake, we propose a new climate interpretation of the sediment record and find further evidence reduced mid-Holocene ENSO variability and a ramp up of ENSO variability starting around 1775 cal. years BP.

Climate variability

Coral reefs

El Niño-Southern Oscillation (ENSO)

Lake sediments

tropical Pacific Ocean

Geosciences

Climate models

Population Fluctuation of the Nodular Coral Psammocora stellata in the Galápagos Islands, Ecuador: An Indicator of Community Resilience and Implications for Future Management

Brown, Kathryn

13 April 2016

Corals are experiencing a worldwide decline in abundance and diversity. Reasons for this include anthropogenic impacts and associated changes to environmental conditions, including global climate change. Increasing atmospheric CO2 levels lead to a coordinated increase in sea surface temperatures and decrease in oceanic pH. Warming events associated with El Niño-Southern Oscillation (ENSO) amplify the impacts of steadily increasing temperatures. For example, coral communities in the Galápagos Islands experienced mortality rates of up to 95-99% during severe ENSO warming in 1982-1983. Persisting through such extreme conditions imposes additional challenges to survival in already marginal environments for coral growth and development that occur in the eastern tropical Pacific. This study quantifies via photoquadrats population changes in mean live coral cover, density, and colony size over a 7-year period (2004-2011) in a small community of the nodular coral Psammocora stellata located at Xarifa Island in the Galápagos Islands. The physical characteristics of this shallow (1-3 m depth) habitat include shading by tall basalt cliffs and strong water flushing action that may contribute to the persistence of this species at this atypical locality through mitigation of anomalously warm and cold conditions. Coral cover is high for this region, and significantly increased from 39.7% in 2004 to 58.3% in 2011 (p=0.006, Tukey HSD), an overall increase of 47%. Fluctuations in coral cover were associated with anomalous temperatures (up to +3.5° and -4.6° C compared to daily means). Negative temperature anomalies in 2007 were associated with a non-significant decrease in coral cover (55.3% in 2007 to 49.5% in 2009), and coral cover rebounded in 2011 to 58.3%. From 2004 to 2011 colony density increased significantly, from 258±62 to 612±245 colonies m-2 (p2 (pin situ, documenting values that ranged from 16.8° - 28.9° C. The persistence of the Psammocora community through both strong and moderate ENSO events demonstrates the resistance and resilience of the species to these temperature anomalies. Adding to the understanding of this species and its interactions with the surrounding physical processes will aid in the development and improvement of management strategies.

Psammocora stellata

Stellar coral

Galápagos Islands

Eastern tropical Pacific

Coral community

Resistance

Resilience

Marine Biology

On the uncertainties and dynamics of Pacific interannual and decadal climate variability and climate change

Furtado, Jason C.

11 November 2010

Tropical and extratropical Pacific decadal climate variability substantially impact physical and biological systems in the Pacific Ocean and strongly influence global climate through teleconnection patterns. Current understanding of Pacific decadal climate variability centers around the El Niño-Southern Oscillation (ENSO), the Aleutian Low (AL), and the Pacific Decadal Oscillation (PDO). However, recent literature has highlighted the emerging roles of secondary modes of variability of the tropical and extratropical Pacific atmosphere and ocean in global climate change: the Central Pacific Warming (CPW) phenomenon, the North Pacific Oscillation (NPO), and the North Pacific Gyre Oscillation (NPGO). This work analyzes the statistics and uncertainties behind Pacific interannual and decadal-scale climate variability, and focuses on better understanding the roles of the CPW, NPO, and NPGO in the climate system. The study begins by examining the dynamics of the NPO and its role in Pacific interannual and decadal climate variability. Results illustrate that the individual poles of the NPO have relations at high frequencies, but only the southern node contains a deterministic low-frequency component, which is forced by tropical Pacific sea surface temperature (SST) variability, as shown with a modeling experiment. The NPO-induced variability by the tropical Pacific SST is then integrated by the underlying ocean surface to form the decadal-scale NPGO signal. Thus, a new link between the CPW, the NPO, and the NPGO is formed, expanding the current framework of Pacific decadal variability and its implications for weather and climate. The new framework of North Pacific decadal variability (NPDV) is then evaluated in 24 state-of-the-art coupled climate models. Results indicate that the models in general have difficulty reproducing the leading modes of NPDV in space and time, particularly the NPGO mode and its connection to the NPO. Furthermore, most models lack the proper connections between extratropical and tropical Pacific, for both the ENSO/AL/PDO and CPW/NPO/NPGO connections. Improvements in these teleconnections are thus needed to increase confidence in future climate projections. The last part of the dissertation explores further the importance of the CPW mode by comparing and contrasting two popular paleoclimate SST anomaly reconstruction methods used for tropical Indo-Pacific SSTs. The first method exploits the high correlation between the canonical ENSO mode and tropical precipitation; the second method uses a multi-regression model that exploits the multiple modes of covariability between tropical precipitation and SSTs, including the CPW mode. The multi-regression approach demonstrates higher skill throughout the tropical Indo-Pacific than the first approach, illustrating the importance of including the CPW phenomenon in understanding past climates.

North Pacific

Atmospheric circulation

Coupled climate models

IPCC

North Pacific oscillation

Tropical Pacific

Climate change

ENSO

Climatology

Climatic changes

Tropospheric circulation

Paleo-proxies for the thermocline and lysocline over the last glacial cycle in the Western Tropical Pacific

Leech, Peter Joseph

20 September 2013

The shape of the thermocline and the depth of the lysoline in the western tropical Pacific are both influenced by the overlying atmosphere, and both the shape of thermocline and the depth of the lysocline can be reconstructed from foraminifera-based paleo-proxies. Paleoclimate proxy evidence suggests a southward shift of the Intertropical Convergence Zone (ITCZ) during times of Northern Hemisphere cooling, including the Last Glacial Maximum (LGM), 19-23 ka before present. However, evidence for movement over the Pacific has mainly been limited to precipitation reconstructions near the continents, and the position of the Pacific marine ITCZ is less well constrained. In this study, I address this problem by taking advantage of the fact that the upper ocean density structure reflects the overlying wind field. I reconstruct changes in the upper ocean density structure during the LGM using oxygen isotope measurements on the planktonic foraminifera G. ruber and G. tumida in a transect of sediment cores from the Western Tropical Pacific. The data suggest a ridge in the thermocline just north of the present-day ITCZ persists for at least part of the LGM, and a structure in the Southern Hemisphere that differs from today. The reconstructed structure is consistent with that produced in a General Circulation Model with both a Northern and Southern Hemisphere ITCZ. I also attempt to reconstruct the upper ocean density structure for Marine Isotope Stages 5e and 6, the interglacial and glacial periods, respectively, previous to the LGM. The data show a Northern Hemisphere thermocline ridge for both of these periods. There is insufficient data to draw any conclusions about the Southern Hemisphere thermocline. Using the same set of sediment cores, I also attempt to reconstruct lysocline depth over the last 23,000 years using benthic foraminiferal carbon isotope ratios, planktonic foraminiferal masses, and sediment coarse fraction percentage. Paleoclimate proxy evidence and modeling studies suggest that the deglaciation following the LGM is associated with a deepening of the lysocline and an increase in sedimentary calcite preservation. Although my data lack the resolution to constrain the depth of the lysocline, they do show an increase in calcite preservation during the last deglaciation, consistent with lysocline deepening as carbon moves from the deep ocean to the atmosphere.

Western Tropical Pacific

Thermocline

Lysocline

Intertropical convergence zone

Last glacial maximum

Foraminifera

Oxygen isotopes

Ocean-atmosphere interaction

Thermoclines (Oceanography)

Marine meteorology

Last Glacial Maximum

Geochemistry of karst deposits in Borneo detailing hydroclimate variations in the Warm Pool across the late Pleistocene

Carolin, Stacy Anne

27 August 2014

Variability in the tropical ocean-atmospheric system causes global scale climate anomalies, most evident in the El Niño-Southern Oscillation’s coupled climate feedbacks. Despite being an area of high interest, many questions still remain regarding the west Pacific warm pool’s response to external forcing, particularly its response to increases in anthropogenic greenhouse gases. Paleoclimate reconstructions coupled with model simulations provide insight into the tropical Pacific’s role in past climate variability necessary to the development of robust climate projections. Most paleoclimate records, however, still lack the resolution, length, and chronological control to resolve rapid variability against a background of orbital-scale variations. Here we present stalagmite oxygen isotope (δ18O) reconstructions from Gunung Mulu National Park (4oN, 115oE ), in northern Borneo, that provide reproducible centennial-scale records of western Pacific hydrologic variability that are precisely U/Th-dated and continuous throughout most of the late Pleistocene (0-160 thousand years ago, kybp). The record comprises an entire glacial-interglacial cycle, which allows us to investigate orbital-scale climate forcings and compare two well-dated glacial terminations in the western tropical Pacific. The ice- volume-corrected δ18O records suggest that glacial boundary condtions, which include significantly lower atmospheric carbon dioxide levels, did not drive significant changes in Mulu rainfall δ18O. Similarly, Borneo stalagmite δ18O is poorly correlated to either global sea level shifts or Sunda Shelf areal exposure is not evident. The Borneo record does vary in phase with local mid-fall equatorial insolation, suggesting that precessional forcing may impart a strong influence on hydroclimate variability in the warm pool. This is best illustrated across Glacial Termination II, when the oscillation of equatorial fall insolation is large and out of phase with ice sheet decay. We also use a subset of well-dated, high-resolution stalagmite δ18O records from Mulu to investigate millennial-scale climate variability during Marine Isotope Stages 3-5 (30-100kybp). We find that regional convection likely decreased during the six massive iceberg discharges defined in the North Atlantic sediment records (“Heinrich events”). The inferred drying (increased stalagmite δ18O) during Heinrich events is consistent with a southward shift of the Intertropical Convergence Zone – the dominant paradigm to explain global climate anomalies originating in the north Atlantic (ref). However, any hydrologic variability related to Dansgaad-Oeschgar (D/O) events, millennial-scale sawtooth temperature anomalies of the last glacial period first evident in the Greenland ice records, is notably absent in the stalagmite records. . The Mulu stalagmite record’s absence of D/O signal, however, is in marked contrast to the regional west Pacific marine records and suggests D/O events and Heinrich events may be characterized by fundamentally different climate mechanisms and feedbacks.

Western tropical Pacific

Oxygen isotopes

U-series dating

Abrupt climate change

Glacial-interglacial cycles

Hydrology

Hydroclimate

Stalagmites

Karst system

Warm pool

Late pleistocene

Glacial period

Dynamique méso-sousmésoéchelle et marée interne dans le Pacifique tropical : implications pour l'altimétrie et la mer des Salomon / Meso-submescale dynamic and internal tide in the tropical Pacific : implications for altimetry and Solomon sea

Tchilibou, Michel Lionel

20 December 2018

Ce travail de thèse est une contribution à la description des signaux océaniques de fines échelles dans les tropiques, fines échelles objet de la futur mission altimétrique SWOT. Ces fines échelles spatiales concernent à la fois des phénomènes dits de méso et sous mésoéchelle, produits par la dynamique océanique (tourbillons, filaments) mais aussi des ondes internes (dont la marée barocline ou marée interne). Les fines échelles sont une source importante de mélange pour l'océan. La méso et sous mésoéchelle océanique traduisent une dynamique turbulente associée à des cascades d'énergie donnant lieu à des pentes spectrales sur des spectres en nombre d'onde de niveau de la mer ou d'énergie cinétique tourbillonnaire. Les pentes spectrales des spectres du niveau de la mer altimétrique sont calculées dans la bande 250-70 km, ces pentes sont très plates dans les tropiques. Par conséquence, elles sont en désaccord aussi bien avec les théories de la turbulence qu'avec les pentes des spectres du niveau de la mer des modèles numériques. Cette thèse vise à élucider ces désaccords dans le Pacifique tropical (20°S-20°N), en quantifiant les niveaux d'énergie et les longueurs d'onde relatives à la dynamique méso-échelle et aux ondes internes. L'importance de la marée interne dans les tropiques est illustrée dans le contexte régional de la mer des Salomon, où cette marée contribue à un fort mélange dans une zone de connexion entre la région subtropicale et la région équatoriale. La première partie de la thèse est une analyse spectrale 3D (fréquence, longueurs d'ondes zonales et méridiennes) de la dynamique tropicale à partir d'un modèle au 1/12°. La région équatoriale (10°N-10°S) se caractérise par une dynamique grande échelle zonale associée aux ondes équatoriales et une dynamique fine échelle (< 600 km) marquée par des mouvements préférentiellement méridiens en lien avec les ondes tropicales d'instabilité. Dans les régions non équatoriales (entre 10° et 20° de latitude) la fine échelle est davantage isotropique, concentrée dans la bande 300-70 km, et connectée à la grande échelle zonale par un continuum d'énergie traduisant l'importance de la cascade inverse. Les pentes des spectres en nombre d'onde de niveau de la mer relatives à la méso/sous-méso échelle des différentes régions sont curieusement proches des pentes théoriques typiques des moyennes latitudes,mais restent en désaccord avec celles issues des observations altimétriques. [...] / This thesis work contributes to our understanding of the fine scale oceanic signals in the tropics, that are the focus of attention for the future altimeter mission SWOT. These fine scales concern meso and submesoscale due to ocean dynamics (eddies, filaments) and internal waves such as the barocline or internal tide. Fines scales are important source of ocean mixing. Meso and submesoscale reflect turbulent dynamic associated with energy cascades giving rise to sea surface height or eddie kinetic wavenumber spectrum slope. The observed altimetric sea surface height spectral slope evaluated in the band 250-70 km are very flat in the tropics. They disagree with turbulence theories and with sea surface height spectral slope of the numerical model. This thesis aims to remove the ambiguity of this spectra flattening in the tropical Pacific (20°S-20°N) by quantifying energy levels and wavelengths related to mesoscale dynamics and internal waves. The importance of the internal tide in the tropics is then illustrated in a regional context in the Solomon Sea, where water mass mixing plays an important role in the connections between the subtropical region and the equatorial region. The first part of the thesis is based on a 3D spectral analysis (frequency, zonal and meridional wavelengths) of tropical dynamics from a 1/12° model. The equatorial region (10°N-10°S) is characterized by large zonal dynamics associated with equatorial waves and finer scale dynamics ( < 600 km) marked by preferentially meridional movements associated with tropical instabilities waves. In the non-equatorial regions (10°-20°NS) the finer scales are more isotropic and concentrated in the band 300-70 km, and are connected to the large zonal scales by an energy continuum reflecting the importance of the indirect cascade. The slopes of the modelled sea surface height wavenumber spectra over the meso/submesoscale band in the different tropical regions are curiously close to the QG/SQG theoretical spectra typical of mid latitudes, but the slopes disagree with those from altimetry observations. Including the high frequency internal waves in a 1/36° model forced by the barotropic tide shows that coherent (predictable) internal tide is the main contributor causing the flattening of the spectra in the tropics, and particularly the M2 first baroclinic mode. However, the contribution of the incoherent (non-predictable) tide dominates at scales below 70 km and still affects scales up to 200 km. [...]

Pacifique tropical

Méso-sousmesoéchelle

Marée interne

Spectre

Mer des Salomon

Masse d'eaux

Tropical Pacific

Meso-submesoscale

Internal tides

Spectrum

Solomon sea

Water mass

FORAGING ECOLOGY OF NESTING GREEN, OLIVE RIDLEY, AND LEATHERBACK TURTLES FROM NORTHWEST COSTA RICA

Alison Jenele Meeth (10716291)

28 April 2021

<div>Understanding what sea turtles are feeding on and where they are feeding is key to understand their overall biology and will aid in understanding what type of management actions are necessary in order to conserve and protect these endangered species. Here I set out to (1) examine the population-level isotopic profiles of three sea turtle species in the Eastern Tropical Pacific; (2) determine differences in their foraging strategies; (3) attempt to gain insights about their pre-nesting origins; and (4) determine whether body size would influence the isotopic values of an individual turtle.</div><div>Stable isotope analysis (δ¹³C and δ¹⁵N values) was conducted on tissue samples from 52 sea turtles nesting on Playa Cabuyal, Costa Rica; 28 Pacific green (<i>Chelonia mydas</i>), 20 olive ridley (<i>Lepidochelys olivacea</i>), and 4 leatherback (<i>Dermochelys coriacea</i>). Nine satellite transmitters were also deployed on a separate population of post-nesting Pacific green turtles from Playa Cabuyal.</div><div>Based on isotopic profiles, green turtles in the Eastern Tropical Pacific were found to be feeding at a higher trophic level when compared to green turtles in other regions and this was supported by their increased δ¹⁵N values (16 ± 0.8 ‰). Rather than shifting to herbivory as adults, green turtles foraging in the eastern Pacific are potentially remaining omnivorous. Tracking data further confirmed that green turtles are coastal migrators and are probably inhabiting areas with high δ¹⁵N values within this region. Olive ridley turtles are exhibiting similar behavior to olive ridley turtles elsewhere due to minimal variance in their isotopic profiles (δ¹³C = -15.1 ± 0.7 ‰, δ¹⁵N =14.2 ± 0.8 ‰) and their known nomadic behavior. Although a small sample size, leatherback turtles showed a shift in their foraging habitats suggesting they are also feeding inshore in addition to their pelagic behavior due to their increased δ¹³C values (-15.5 ± 0.4 ‰). Further, as body size increased in olive ridley’s, the δ¹⁵N values significantly decreased suggesting that larger turtles prefer deeper pelagic waters with less enriched N isotope concentrations. However, in order to rule out possible external factors influencing this relationship, knowing where the turtle is originating from is crucial. This project provides data for developing isoscapes in the Eastern Tropical Pacific to aid in understanding the spatial distribution of sea turtles and their foraging grounds and the impact that foraging area may have on overall biology of these species. This information can be used to prioritize high use foraging habitats and determine the most effective management practices for protecting these species and the prey and habitat on which they rely.</div>

sea turtles

Chelonia mydas

Lepidochelys olivacea

Dermochelys coriacea

stable isotope analysis

carbon

nitrogen

satellite telemetry

Eastern Tropical Pacific

Late Campanian-Maastrichtian Planktic Foraminiferal Biostratigraphy, Taxonomy, and Isotope Paleoecology of Odp Leg 198 Sites 1209 and 1210, Shatsky Rise

Clark, Kendra R

01 January 2012

Well-preserved and diverse assemblages of late Campanian-Maastrichtian age (76.5-65.5 Ma) planktic foraminifera from Ocean Drilling Program Sites 1209 and 1210 on Shatsky Rise provide an excellent source of data to better understand the environmental and biotic changes of the end-Cretaceous Period in the tropical Pacific. A thorough taxonomic and biostratigraphic study of planktic foraminifera has revealed significant differences in species ranges when compared to detailed studies from the western North Atlantic and eastern South Atlantic. These observations are attributed to site locations with different ocean current and productivity conditions. During the globally recognized “mid-Maastrichtian Event”, inoceramid clams, rare at Shatsky Rise, dramatically increased (~69.3 Ma) before suddenly going extinct (69.1 Ma). This Inoceramid Acme Event (IAE), occurs during high sedimentation rates (~21.8-m/myr) and is indicated in planktic foraminifera by a 0.50‰ positive shift in δ18O values (~2 °C cooling), a 0.24‰ negative shift in δ13C values of and high species richness. A simultaneous decrease in both the δ18O and δ13C gradients between surface and thermocline dwelling planktic foraminifera indicate the IAE was possibly initiated by an increase in surface productivity due to the upwelling of cooler, nutrient-rich waters. A dissolution event was identified at ~66.1 Ma lasting to the Cretaceous/Paleogene boundary (65.5 Ma) and is characterized by chalky, highly fragmented planktic foraminifera, increased dissolution of larger Globotruncanids, increased small (< 63 μm) planktic foraminifera, large and increasingly abundant benthic foraminifera, a sharp decrease in species richness and increased sedimentation rates (~19.9-m/myr). This event follows a transitional interval at ~66.7 Ma where preservation is highly variable. The dissolution event, reported in previous studies at Shatsky Rise (Caron, 1975; Premoli Silva et al., 2005), is not reported in the North and South Atlantic but may help to explain the high diachroneity in species occurrences between ocean basins. These events may indicate that the calcite carbonate compensation depth (CCD) shoaled to shallower depths than previously reported (Theirstein, 1979) due to changing deep or intermediate water mass sources. Alternatively, the timing the dissolution is approximately coincident with the main pulse of Deccan Trap volcanism on the Indian subcontinent suggesting a possible link through ocean acidification.

late Campanian-Maastrichtian

Shatsky Rise-tropical Pacific

paleoceanography

Mid-Maastrichtian Event

dissolution

Climate

Geology

Oceanography

Paleontology

Stratigraphy

Le niveau de la mer actuel : variations globales et régionales / Present day sea level : global and regional variations

Kulaiappan Palanisamy, Hindumathi

06 January 2016

Le niveau de la mer est une des variables climatiques essentielles dont la variabilité résulte de nombreuses interactions complexes entre toutes les composantes du système climatique sur une large gamme d'échelles spatiales et temporelles. Au cours du XXème siècle, les mesures marégraphiques ont permis d'estimer la hausse du niveau de la mer global entre 1,6 mm/an et 1,8 mm/an. Depuis 1993, les observations faites par les satellites altimétriques indiquent une hausse du niveau de la mer plus rapide de 3,3 mm/an. Grâce à leur couverture quasi-globale, elles révèlent aussi une forte variabilité du niveau de la mer à l'échelle régionale, parfois plusieurs fois supérieure à la moyenne globale du niveau de la mer. Compte tenu de l'impact très négatif de l'augmentation du niveau de la mer pour la société, sa surveillance, la compréhension de ses causes ainsi que sa prévision sont désormais considérées comme des priorités scientifiques et sociétales majeures. Dans cette thèse, nous validons d'abord les variations du niveau de la mer mesurées par la nouvelle mission d'altimétrie satellitaire, SARAL-AltiKa, en comparant les mesures avec celles de Jason- 2 et des marégraphes. Un autre volet de cette première partie de thèse a consisté à estimer les parts respectives des facteurs responsables des variations du niveau de la mer depuis 2003 en utilisant des observations issues de l'altimétrie satellitaire (missions altimétrique Jason-1, Jason-2 et Envisat), de la mission GRACE, et des profils de température et salinité de l'océan par les flotteurs Argo. Une attention particulière est portée à la contribution de l'océan profond non 'vue' par Argo. Nous montrons que les incertitudes dues aux approches du traitement des données et aux erreurs systématiques des différents systèmes d'observation nous empêchent encore d'obtenir des résultats précis sur cette contribution. Dans la deuxième partie de la thèse, en utilisant les données de reconstruction du niveau de la mer dans le passé, nous étudions la variabilité régionale du niveau de la mer et estimons sa hausse totale (composante régionale plus moyenne globale) de 1950 à 2009 dans trois régions vulnérables: l'océan Indien, la mer de Chine méridionale et la mer des Caraïbes. Pour les sites où l'on dispose de mesures du mouvement de la croûte terrestre par GPS, nous évaluons la hausse locale du niveau de la mer relatif (hausse du niveau de la mer totale plus mouvement de la croûte locale) depuis 1950. En comparant les résultats de ces trois régions avec une étude précédente sur le Pacifique tropical, nous constatons que le Pacifique tropical présente la plus forte amplitude des variations du niveau de la mer sur la période d'étude. Dans la dernière partie de la thèse, nous nous concentrons par conséquent sur le Pacifique tropical. Nous analysons les rôles respectifs de la dynamique océanique, des modes de variabilité interne du climat et du forçage anthropique sur les structures de la variabilité régionale du niveau de la mer du Pacifique tropical depuis 1993. Nous montrons qu'une partie importante de la variabilité régionale du niveau de la mer du Pacifique tropical peut être expliquée par le mouvement vertical de la thermocline en réponse à l'action du vent. En tentant de séparer le signal correspondant au mode de variabilité interne du climat de celui de la hausse régionale du niveau de la mer dans le Pacifique tropical, nous montrons également que le signal résiduel restant (c'est-à-dire le signal total moins le signal de variabilité interne) ne correspond probablement pas à l'empreinte externe du forçage anthropique. / Sea level is an integrated climate parameter that involves interactions of all components of the climate system (oceans, ice sheets, glaciers, atmosphere, and land water reservoirs) on a wide range of spatial and temporal scales. Over the 20th century, tide gauge records indicate a rise in global sea level between 1.6mm/yr and 1.8 mm/yr. Since 1993, sea level variations have been measured precisely by satellite altimetry. They indicate a faster sea level rise of 3.3 mm/yr over 1993-2015. Owing to their global coverage, they also reveal a strong regional sea level variability that sometimes is several times greater than the global mean sea level rise. Considering the highly negative impact of sea level rise for society, monitoring sea level change and understanding its causes are henceforth high priorities. In this thesis, we first validate the sea level variations measured by the new satellite altimetry mission, SARAL-AltiKa by comparing the measurements with Jason-2 and tide gauge records. We then attempt to close the global mean sea level budget since 2003 and estimate the deep ocean contribution by making use of observational data from satellite altimetry, Argo profiles and GRACE mission. We show that uncertainties due to data processing approaches and systematic errors of different observing systems still prevent us from obtaining accurate results. In the second part of the thesis, by making use of past sea level reconstruction, we study the patterns of the regional sea level variability and estimate climate related (global mean plus regional component) sea level change over 1950-2009 at three vulnerable regions: Indian Ocean, South China and Caribbean Sea. For the sites where vertical crustal motion monitoring is available, we compute the total relative sea level (i.e. total sea level rise plus the local vertical crustal motion) since 1950. On comparing the results from these three regions with already existing results in tropical Pacific, we find that tropical Pacific displays the highest magnitude of sea level variations. In the last part of the thesis, we therefore focus on the tropical Pacific and analyze the respective roles of ocean dynamic processes, internal climate modes and external anthropogenic forcing on tropical Pacific sea level spatial trend patterns since 1993. Building up on the relationship between thermocline and sea level in the tropical region, we show that most of the observed sea level spatial trend pattern in the tropical Pacific can be explained by the wind driven vertical thermocline movement. By performing detection and attribution study on sea level spatial trend patterns in the tropical Pacific and attempting to eliminate signal corresponding to the main internal climate mode, we further show that the remaining residual sea level trend pattern does not correspond to externally forced anthropogenic sea level signal. In addition, we also suggest that satellite altimetry measurement may not still be accurate enough to detect the anthropogenic signal in the 20 year tropical Pacific sea level trends.

Hausse du niveau de la mer

SARAL-AltiKa

Bilan du niveau de la mer

Contribution l'océan profond

Pacifique tropical

Thermocline

Mode de la variabilité interne

Impacts anthropiques

Sea level rise

SARAL-AltiKa

Global mean sea level budget

Deep ocean contribution

Regional sea level variability

Total relative sea level change

Tropical Pacific

Thermocline

Internal climate mode

Anthropogenic sea level fingerprint