[PhD position] DustDN Doctoral Network DC12 - Modelling the effects of dust upon regional climate with constrained dust-source mineralogy (R1)

The Barcelona Supercomputing Center - Centro Nacional de Supercomputación (BSC-CNS) is the leading supercomputing center in Spain. It houses MareNostrum, one of the most powerful supercomputers in Europe, was a founding and hosting member of the former European HPC infrastructure PRACE (Partnership for Advanced Computing in Europe), and is now hosting entity for EuroHPC JU, the Joint Undertaking that leads large-scale investments and HPC provision in Europe. The mission of BSC is to research, develop and manage information technologies in order to facilitate scientific progress. BSC combines HPC service provision and R&D into both computer and computational science (life, earth and engineering sciences) under one roof, and currently has over 1000 staff from 60 countries.

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We are particularly interested for this role in the strengths and lived experiences of women and underrepresented groups to help us avoid perpetuating biases and oversights in science and IT research. In instances of equal merit, the incorporation of the under-represented sex will be favoured.

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If you consider that you do not meet all the requirements, we encourage you to continue applying for the job offer. We value diversity of experiences and skills, and you could bring unique perspectives to our team.

The Dust-DN doctoral network

Atmospheric dust or mineral dust (or simply “dust”) is a major atmospheric aerosol, and it gives us one of the most visible and detectable aspects of transboundary transport of atmospheric constituents, impacting visibility, radiation and climate. What is less evident are its quantitative impacts on health, transportation and energy production. Atmospheric dust is not fully understood at the fundamental level (microphysical properties, dust emissions, source regions) and hence atmospheric models fail to fully reproduce its impacts. Moreover, dust observations using ground-based instrumentation, remote sensing and aircraft are abundant, but not evenly distributed; in particular they are missing near the major dust sources. Moreover, the techniques are still under development, with each giving a different picture of a phenomenon with multiple facets. For example, it is now known that super-coarse and giant dust particles have gone undetected for a long time due to limitations in the measurement and modelling tools that have been in use for decades, and this misdetection alters the understanding and the prediction of a number of processes. Finally, dust affects the environment, society, and several economic sectors, with impacts on the transportation and energy sectors for example, the nature and cost of which is not fully understood and quantified. Several methodologies exist to study mineral dust, each giving its own differing picture of a complex phenomenon: numerical modelling, remote sensing, in-situ observations, laboratory research.

We establish the Dust Doctoral Network (Dust-DN), in order to address gaps in the understanding of dust and its impacts by linking the different disciplines and methods. The aim is to train a team of early career scientists into overcoming compartmentalism in this field of science, and into developing a multi-disciplinary approach to mineral dust. Dust-DN will set up a network of academic and non-academic partners working on different aspects of dust research, and will coordinate a program of doctoral projects that will enhance knowledge across a broad range of fundamental, but linked, components of the atmospheric dust life cycle and its impacts. The projects will span across the disciplines of atmospheric sciences (dust processes, modelling, and remote sensing), geology (dust emissions and source regions), as well as the impacts on society and economic sectors. The knowledge will be shared among participating institutions and the wider public and scientific community. Common activities will be held, so as to enhance the network among the partner institutions and among the doctoral researchers, delivering an ambitious advanced training program for capacity building.

The selected candidate will join the Atmospheric Composition (AC) group within the Earth Sciences Department of the BSC (BSC-ES). The AC group is composed of more than 40 scientists and engineers and seeks to understand the sources, sinks, atmospheric lifecycles, and effects of atmospheric pollutants across a broad range of spatiotemporal scales, from local to global and from short- (weather) to long-term (climate) scales. The group develops atmospheric chemistry and Earth System models, operates air quality forecasting systems, and applies its knowledge in cross-cutting research, addressing issues such as air quality policy, and socio-economic impacts such as health. The AC group hosts the WMO Sand and Dust Storm Warning Advisory and Assessment System Regional Center for North Africa, the Middle East and Europe, and an AXA Chair on Sand and Dust Storms. The group actively participates in the NASA’s EMIT (Earth Surface Mineral Dust Source Investigation) instrument mission, hosts an ERC Consolidator Grant (FRAGMENT) on the effects of dust mineralogy upon climate, and is involved in numerous European projects tackling aerosol effects on climate (e.g., FORCeS, FOCI, CERTAINTY).

The doctoral project

Doctoral Candidate 12 (DC12) – “Modelling the effects of dust upon regional climate with constrained dust-source mineralogy”

Enrolled in the Universitat Politècnica de Catalunya (UPC) PhD programme on “Environmental Engineering”, the doctoral candidate will develop the research at BSC-ES.

Soil dust aerosols are mixtures of different minerals, whose relative abundances, particle size distribution (PSD), shape, surface topography and mixing state influence their effect upon climate. However, most current models typically assume that dust aerosols have a globally uniform composition, neglecting the known regional variations in the mineralogy of the sources, and those which include composition variations use poorly constrained soils mineralogical atlases. This project has the objective of improving our knowledge on the effect of dust mineralogical composition in climate, a research field which still holds great uncertainty. The doctoral candidate will work with a model to represent spatially resolved mineralogy of dust sources based on novel EMIT satellite data. The model results will be evaluated against in-situ, remote and satellite observations. These new model developments will allow assessing the climate response to dust radiative effects at high resolution, with special emphasis in Northern Africa, the Middle East and Europe.

The doctoral candidate will be based at BSC in Barcelona, Spain and will be supervised by Dr. María Gonçalves Ageitos (BSC/UPC) and Prof. Carlos Pérez García-Pando (BSC). The project will include three planned secondments of 1 month each, consisting of one at the National Observatory of Athens (NOA), with Dr. Vassilis Amiridis, to explore the links between mineralogy and improved representation of dust transport in a modelling framework, one at Technical University of Darmstadt (TUDa), with Dr. Konrad Kandler, to bring in additional observational constraints on dust mineralogy, and one at the Karlsruhe Institute of Technology (KIT), with Dr. Martina Klose, to improve the representation of high resolution emission processes and link them to dust mineralogy.