Hiring Institution
Université Grenoble Alpes (UGA)

PhD-Awarding Institutions
Université Grenoble Alpes (UGA)
University of Tasmania (UTAS)

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Option 1

Climate and carbon cycle interactions across the Mid-Pleistocene Transition

The climate across the Quaternary (the last 2.58 million years), is punctuated by warm periods known as interglacials, characterized by reduced ice cover on Northern Hemisphere continents, and they alternate with cold periods, referred to as glacial periods characterized by large ice caps in the Northern Hemisphere. The cyclicity associated with this succession of glacial-interglacial periods changed between 1.2 Ma and 800 thousand of years (ka) ago, from ~41 to 100 ka. This major change in the climate system is referred to as the Middle Pleistocene Transition (MPT) and the responsible processes are not fully understood yet. Amongst the existing hypotheses, it has been suggested that changes in the carbon cycle dynamics have played a triggering role.

The past 2 Ma are covered by natural climate archives (e.g. marine sediments, loess). Each archive has its own specific characteristics, providing a different view of past climates and information on different components of the Earth system (e.g. cryosphere, ocean, vegetation). In particular, indirect reconstructions of atmospheric CO₂ concentrations from marine sediments are available across the MPT however discrepancies between them currently exist. In addition, to interpret climate and atmospheric records and identify the sequence of changes in different parts of the world, precise dating of the natural archives is essential. However, it is challenging to achieve that far back in time and it results that most climatic records are attached to large dating uncertainties of several millennia. The current lack of global-scale data compilation relying on a coherent temporal framework over the past 2 Ma as well as uncertainties attached to atmospheric CO₂ reconstructions prevent a refined investigation of the regional temporal structure of the climate and environmental changes across the MPT and of their link to changes in carbon cycle dynamics.

In this context, the PhD project aims first at constructing a global-scale compilation of climate data from natural archives covering the past 2 Ma. Parameters of interest are surface and sub-surface ocean temperature, ice volume and key markers of ocean circulation, hydrological cycle, ice sheet history and ocean biogeochemistry.

In order to achieve this work, an important task will be to produce a common and robust chronology between the selected paleoclimatic and paleoenvironmental records. For that purpose, a probabilistic dating model will be used. This tool enables to date jointly numerous climate records from different types of natural archives, accounting for various types of chronological constraints and providing also quantitative estimates of the uncertainties attached to the produced age scales. The other aim of this project will be to provide a compilation and assessment of existing CO₂ reconstructions across the MPT, including data obtained from ice cores from blue ice area as well as boron-isotope based proxy-CO₂ reconstructions from marine sediment cores and CO₂ reconstructions from other proxy archives.

The new results will provide the first global-scale spatio-temporal picture of climate, ice sheet and environmental variations across the MPT and will contribute in better understanding the forcing processes for this key climatic transition, and especially the role of changes in the carbon cycle.

Option 2

Global and regional climate & drivers at millennial-to orbital scale during a past warm period (Marine Isotopic Stage 11)

The warm periods (referred to as interglacials) of the last 500,000 years are relevant in the context of the current and future global climate change since they are characterized by a warming amplitude in Antarctica, comparable to that simulated for the end of the century. They represent natural laboratory to study processes within the Earth system and to understand the impact of a warm climate on its vulnerable components. In particular, the interglacial referred to as Marine Isotopic Stage 11 (hereafter noted MIS 11) that occurred about 410 thousand of years ago is one of the most prominent past interglacials during which global sea level was 9-13 m higher than today. Thus, MIS 11 is a unique period of climate to investigate the impact of climate warming on the polar ice sheets and ocean circulation. Numerous paleoclimatic records from different natural archives (e.g. polar ice cores, marine sediments and cave speleothems) cover this period. Each archive has its own specific characteristics, providing a different view of past climates and information on different components of the Earth system (e.g. cryosphere, ocean, vegetation). To interpret these climate records and identify the sequence of changes in different parts of the world, precise dating of the natural archives is essential. However, it is challenging to achieve that far back in time and it results that most climatic records are attached to large dating uncertainties of several millennia. The current lack of global-scale data compilation relying on a robust temporal framework across MIS 11 prevents a refined characterisation on the sequence of climate changes in different parts of the world. It also hinders the identification of the climate mechanisms and feedbacks during this period.

In this context, the PhD project aims at constructing a global-scale compilation of climatic data (e.g. sea and air surface temperatures, oceanic circulation intensity, sea level, hydrological cycle) from ice cores, marine sediment cores and speleothems covering MIS 11 to provide the spatio-temporal picture of climate variations across this past warm time interval and to progress on our understanding of the forcing processes.

In order to achieve this, an important task will be to produce a common and robust chronology between the selected paleoclimatic and paleoenvironmental records. For that purpose, a probabilistic dating model will be used. This tool enables to date jointly numerous climate records from different types of natural archives, accounting for various types of chronological constraints and providing also quantitative estimates of the uncertainties attached to the produced age scales. This dating effort will be essential to characterize eventually the amplitude of the climate warming during Marine Isotopic Stage 11, its spatial and temporal evolution, and more broadly, the sequences of events between climate, ocean circulation and polar ice sheets in a past warm world.

Also, the new results will be used to evaluate existing and up-coming Earth System Model simulations run across MIS 11 in order to identify with those physics-based tools the climate forcing and feedbacks at play during this interglacial.Overall, these results will provide (i) a better understanding of the impacts of a warm climate on the vulnerable components of the Earth system and (ii) testbeds for evaluating how well Earth System Models simulate warm climates, contributing in improving future climate projections.

Option 3

Optimal dating of Antarctic deep ice cores & millennial-scale regional climatic changes over the last glacial-interglacial cycle

The last glacial-interglacial cycle (past 120 000 years) is one of the most studied periods in paleoclimatology due to its high coverage by natural climate archives (e.g. polar ice cores, marine sediments and cave speleothems). Also, it provides unique insights into several windows of past climate changes that are relevant to study in the context of our warming planet. For instance, multiple centennial-to-millennial scale warming events have been identified in Greenland and Antarctic ice cores during the glacial period. In addition, the last deglaciation was associated with a 4°C global warming and global sea level rise up to about 120 m that included several periods of abrupt regional temperature and global sea level change. Hence, these time periods represent great testbeds to look into the interactions between climate, the carbon cycle and the polar ice sheet evolution.

In this context, deep Antarctic ice cores provide reference records since they enclose various chemical parameters that can be linked to different parts of the Earth System and they record global atmospheric composition changes in the trapped air. To interpret these climate records and identify the sequence of changes in different parts of the world, a precise dating of both the ice phase and the gas phase is essential. Back in 2013, a common temporal framework (named AICC 2012) was built between four Antarctic ice cores and one Greenland ice cores. New dating constraints have been produced since then for these ice cores and there are also temporal divergences of up to several thousands of years that still exist with the Antarctic ice cores that were not included in this effort. However, those recent ice cores drilled mainly in coastal areas of Antarctica enclose valuable regional climatic information at a relatively high temporal
resolution.

This PhD project aims at combining all the chronological information available from deep ice cores drilled both in central and coastal Antarctica to produce a new reference Antarctic ice core chronology over the last glacial-interglacial cycle. Chronological information from the well-dated cave speleothems will also be included to constrain this new timescale.

In order to produce this reference chronology, a new probabilistic dating model will be used. This tool enables to date jointly numerous climate records from different types of natural archives, accounting for various types of chronological constraints and providing also quantitative estimates of the uncertainties attached to the produced optimized age scales.

Based on this new chronology, it will be possible to provide new insights on (1) the spatio-temporal evolution of the millennial-scale climate variability and (2) the timing and structure of the last deglaciation across Antarctica and (3) their links with Antarctic ice sheet changes.

Dr Emilie Capron
Dr. Frédéric Parrenin
Dr Joel Pedro
Taryn Noble
Dr. Andy Menking

Paleoclimatology, glaciology