PhD Position in Energy and Planetary Sciences: Natural Hydrogen and Supercritical CO2 Systems
ETH Zurich
The ETH Zurich Geothermal Energy & Geofluids (GEG.ethz.ch) Group in the Department of Earth and Planetary Sciences investigates subsurface reactive fluid and geothermal energy transfer, developing and employing computer simulations, laboratory experiments, and field analyses. Our aim is to gain fundamental insights and to develop sustainable technologies that address societal needs. Further information about the GEG Group can be found on our website.
Homepage: https://geg.ethz.ch/
Geochemistry, Mineralogy, Petrology & Volcanology (GMPV)
Planetary and Solar System Sciences (PS)
Two PhD Opportunities in Energy and Planetary Sciences: Natural Hydrogen and Supercritical CO₂ Systems 100%, fixed-term
We are excited to announce two interdisciplinary PhD opportunities focused on cutting-edge research in geochemistry, planetary science, and natural hydrogen. The successful candidates will join a dynamic research team to explore fundamental processes in supercritical CO₂ systems with dissolved water and the formation of natural hydrogen in geological environments. This research aims to address pressing questions regarding geological processes on Earth and other planets as well as the potential for energy resources from natural hydrogen.
Job description
For this research, we are looking for applicants with backgrounds in geochemistry and electrochemistry, or closely related fields, to fill two PhD positions with respective foci on: (1) reactivity of hydrous supercritical CO₂ (scCO2) and (2) subsurface production of natural hydrogen.
The PhD position on the reactivity of hydrous scCO₂ will focus on mineral-hydrous scCO₂ reactions, including the dissolution and precipitation of minerals as well as the associated electrochemical processes in CO₂-rich environments with limited dissolved water. This research will have direct applications to natural and artificial CO₂ reservoirs, geologic CO₂ storage, usage of subsurface CO₂ as a geothermal energy extraction fluid, insights into early Earth conditions, and the potential for studying CO₂ interactions on other planets.
The PhD position on natural hydrogen production will focus on the formation, accumulation, and migration of natural hydrogen in subsurface environments. The research aims to explore geochemical processes that lead to natural hydrogen generation, focusing on the potential of natural hydrogen as an energy resource. The research will also extend to the study of hydrogen generation in planetary systems, particularly in the context of (early) life in deep subsurface environments and extraterrestrial settings.
Profile
We seek highly motivated, self-organized individuals with a strong background in geochemistry, planetary science, subsurface energy science, or a related field. Successful candidates will:
- have a keen interest in interdisciplinary research that combines Earth science and energy resources.
- be motivated to conduct innovative research in geochemistry, energy systems, and planetary science.
- have experience in experimental geochemistry, geochemical modeling, or geothermal/fluid systems.
- possess skills in geochemistry measurement techniques such as X-ray diffraction (XRD), scanning electron microscopy (SEM), X-ray computed tomography (XRCT), nuclear magnetic resonance (NMR), or electron paramagnetic resonance (EPR).
- ideally also have expertise in designing and performing high-temperature and high-pressure in situ experiments.
- be near-fluent in English, both written and spoken.
We offer:
- a dynamic and stimulating work environment with cutting-edge computational and laboratory infrastructure - both at ETH Zurich as a whole and within the GEG Group in particular.
- GEG's Reactive Transport Laboratory features an XRCT system for conducting in situ reactive transport experiments, as well as a laser laboratory equipped with Particle Image Velocimetry (PIV) and Laser-Induced Fluorescence (LIF) capabilities.
- The position is 100% with a competitive salary according to ETH Zurich standards. The position is for one year with the potential for annual extensions based on project needs and employee performance. The anticipated position start date is 1st of October 2025 or as soon as possible thereafter.
- we are currently expanding our facilities to include both low - and high-field, multi-nuclide Nuclear Magnetic Resonance (NMR) scanners. These will enable in situ reactive transport experiments, along with the quantification and visualization of a wide range of components, temperature, and pressure in up to three dimensions. The NMR systems will also be equipped with Electron Paramagnetic Resonance (EPR) capabilities. The GEG Group fosters an open, collaborative, and inclusive culture.
We value diversity
In line with our values, ETH Zurich encourages an inclusive culture. We promote equality of opportunity, value diversity and nurture a working and learning environment in which the rights and dignity of all our staff and students are respected. Visit our Equal Opportunities and Diversity website to find out how we ensure a fair and open environment that allows everyone to grow and flourish.
Curious? So are we.
We look forward to receiving online application with the following documents:
- a cover letter, describing your motivation, experience and qualification for the position
- your CV
- diplomas and relevant work certificates
- if readily available, up to three professional reference letters, otherwise, please provide the contact information of up to three references
Please note that we exclusively accept applications submitted through our online application portal. Applications via email or postal services will not be considered.
Questions regarding the position should be directed to Dr. Xiang-Zhao Kong at xkong@ethz.ch (no applications).
We would like to point out that the pre-selection is carried out by the responsible recruiters and not by artificial intelligence.