What is it about?
The article is about very accurate quantum-chemical methods that enable the study of atoms and molecules in very strong magnetic fields, even stronger than anything we can produce on Earth. We describe the theory and the implementation of such methods in a computer program. We also show applications how strong fields lead to changes in properties that would change the chemistry and the spectroscopic signatures of these atoms and molecules.
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Photo by NASA Hubble Space Telescope on Unsplash
Why is it important?
Over 90% of stars that die become so-called white dwarf stars. On such stars one finds magnetic fields that are much larger than the ones we can obtain on Earth. Concretely, they can be as strong as 100000 Tesla. However, we do get spectra, i.e., a fingerprint signatures from the light coming from the atmosphere of the stars, that can in principle tell us which atoms and molecules are to be found there and how large their magnetic field is. These spectra are recorded with Earth-would telescopes or space telescopes like Hubble or James Webb. Because there is no experiment that we could do on Earth to get a spectrum of known composition for comparison, we can however not interpret the obtained spectra. Only with the help of quantum-chemical methods of high accuracy this interpretation (assignment) is possible. In this article, we have formulated such quantum-chemical methods that can predict what spectra of various atoms or molecules would look like in strong magnetic fields. They hence enable the assignment of spectra from white dwarf stars and hence gives us the chance to learn about the universe, white dwarfs and the life cycle of stars in general. The use of these methods has indeed lead to the assignment of a spectrum of a white dwarf star with metals in the atmosphere.
Perspectives
We enjoyed working on this project as it shows the potential of theory to lead to fundamental understanding in astrophysics. Hence, methods that can describe atoms and molecules in a such exotic conditions of very strong magnetic fields open to door to finding more atoms and even molecules in these environment and leads to more interdisciplinary work
Stella Stopkowicz
Universitat des Saarlandes
I enjoyed working in this project, as it showed the potential of theory to capture effects in very exotic environments. The contribution of this work to astrophysics was personally fulfilling, as I have always been fascinated by astronomy and the night sky. I hope this work boosts more interdisciplinary work and lay the foundation for detecting molecules on magnetic White Dwarf stars.
Marios-Petros Kitsaras
Universitat des Saarlandes
Read the Original
This page is a summary of: The approximate coupled-cluster methods CC2 and CC3 in a finite magnetic field, The Journal of Chemical Physics, March 2024, American Institute of Physics,
DOI: 10.1063/5.0189350.
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