Discover the research at Stockholm University through our pages for research subjects, projects and research groups!
They also lead you to our researchers profile pages, our departments and courses and programmes.
Showing 1-20 of 66 results
Quantum mechanical studies of reactive scattering processes are performed involving small reaction complexes in highly excited states where non-adiabatic effects are crucial. The theoretical model is tested by close collaboration with experiments.
We study methods to create and probe atoms and ions made of antimatter, with the purpose to test fundamental symmetries of nature.
Do axions exist, and if so, how do we find them?
The EU-funded BRISQ project will combine trapped ion technology and Rydberg interaction to build a highly promising physical platform to host a scalable quantum computer.
The goal of the CHAMPS project is to develop a new paradigm for nanotechnological research and development based on charged microdroplets produced by electrospray ionization (ESI)
We explore the cosmic content of the universe by measuring the expansion rate using supernovae as distance indicators.
There are many base chemicals of importance for the catalytic production of fertilizers, plastics, detergents, pharmaceuticals and fuels. Currently, the feedstock for the chemical industry is entirely based on fossil sources with an emittance of 8% of the worlds footprint of greenhouse gases (not including when fuels is being burned).
Quantum technology carries the promise to revolutionise data processing, communication, and metrology. The current approach towards unlocking this potential builds on scalable and fully coherent devices with high technological complexity.
This project aims to significantly advance the understanding of charge exchange, energy transfer and bond formation processes in interactions between isolated molecules or clusters and atomic or molecular ions.
This project studies protein crystallization in ferritin microdroplets. Using X-ray Photon Correlation Spectroscopy and facilities like ESRF and Eu-XFEL, it investigates hidden intermediate states and water's role in the crystallization process.
Dosimetric approaches for protection of people in large-scale nuclear emergencies
A project in mathematical physics to understand equilibrium and non-equilibrium properties of deformed or disordered quantum many-body systems.
The purpose of the project is to develop novel superconducting electronics for a future generation of fast and energy-efficient supercomputers. The central idea is to employ quantized Abrikosov vortices as information carriers.
While entanglement is the primary threat of quantum mechanics, it is also the reason why simulating quantum systems by classical means is challenging. We explore complex quantum systems and explore methods for their simulation.
The scientific objective of this RAC consortium is to use advanced X-ray methods in order to study the dynamics of proteins in crowded environments, in condensates and during phase transitions on their relevant length and time scales.
The existence of Dark Matter (DM), matter that is invisible to conventional telescopes has become indisputable. This project employs deep underground detectors for rare events to search for dark matter particles.
Teachers and students at Stockholm university quickly had to adjust to online course delivery in response to the Covid-19 Pandemic. Despite the challenging circumstances, the spring term 2020 provided an opportunity to collect data on how both students andteachers experienced an emergency transition to online teaching.
Mutual Neutralization (MN) is studied at the DESIREE ion-beam storage ring. In MN, an electron is transferred from a negative to a positive ion forming two neutral particles. This fundamental process is important in many natural environment.
The aim of the PANDA experiment is to understand the strong force using very precise accelerated beam of antiprotons. The experiment is part of the research at the accelerator facility FAIR which is under construction in Darmstadt, Germany.
Cells and organisms are differentially sensitive to ionising radiation. What influences the individual response to radiation? We study the role of genetic and environmental factors and try to identify biomarkers of radiation sensitivity and exposure.
