Your search keyword '"Simonsson, Ansgar"' showing total 3 results

1. High-precision electron affinity of oxygen.

Author

Kristiansson, Moa K., Chartkunchand, Kiattichart, Eklund, Gustav, Hole, Odd M., Anderson, Emma K., de Ruette, Nathalie, Kamińska, Magdalena, Punnakayathil, Najeeb, Navarro-Navarrete, José E., Sigurdsson, Stefan, Grumer, Jon, Simonsson, Ansgar, Björkhage, Mikael, Rosén, Stefan, Reinhed, Peter, Blom, Mikael, Källberg, Anders, Alexander, John D., Cederquist, Henrik, and Zettergren, Henning

Subjects

ELECTRON affinity, ANIONS, HYPERFINE coupling, ELECTRON configuration, ION energy, STORAGE rings, ION beams

Abstract

Negative ions are important in many areas of science and technology, e.g., in interstellar chemistry, for accelerator-based radionuclide dating, and in anti-matter research. They are unique quantum systems where electron-correlation effects govern their properties. Atomic anions are loosely bound systems, which with very few exceptions lack optically allowed transitions. This limits prospects for high-resolution spectroscopy, and related negative-ion detection methods. Here, we present a method to measure negative ion binding energies with an order of magnitude higher precision than what has been possible before. By laser-manipulation of quantum-state populations, we are able to strongly reduce the background from photodetachment of excited states using a cryogenic electrostatic ion-beam storage ring where keV ion beams can circulate for up to hours. The method is applicable to negative ions in general and here we report an electron affinity of 1.461 112 972(87) eV for 16O. High-precision measurements are useful to find isotopic shifts and electron correlation. Here the authors measure electron affinity and hyperfine splitting of atomic oxygen with higher precision than previous studies. [ABSTRACT FROM AUTHOR]

Published

2022

2. DESIREE as a new tool for interstellar ion chemistry.

Author

Schmidt, Henning T., Johansson, Henrik A.B., Thomas, Richard D., Geppert, Wolf D., Haag, Nicole, Reinhed, Peter, Rosén, Stefan, Larsson, Mats, Danared, Håkan, Rensfelt, K.-G., Liljeby, Leif, Bagge, Lars, Björkhage, Mikael, Blom, Mikael, Löfgren, Patrik, Källberg, Anders, Simonsson, Ansgar, Paál, Andras, Zettergren, Henning, and Cederquist, Henrik

Subjects

ION beams, RATE coefficients (Chemistry), ELECTROSTATICS, RELATIVE velocity, NEUTRALIZATION (Chemistry)

Abstract

A novel cryogenic electrostatic storage device consisting of two ion-beam storage rings with a common straight section for studies of interactions between oppositely charged ions at low and well-defined relative velocities is under construction at Stockholm University. Here we consider the prospect of using this new tool to measure cross-sections and rate coefficients for mutual neutralization reactions of importance in interstellar ion chemistry in general and specifically in cosmic pre-biotic ion chemistry. [ABSTRACT FROM AUTHOR]

Published

2008

3. The mutual neutralization of hydronium and hydroxide.

Author

Bogot, Alon, Poline, Mathias, MingChao Ji, Dochain, Arnaud, Simonsson, Ansgar, Rosén, Stefan, Henning Zettergren, Schmidt, Henning T., Thomas, Richard D., and Strasser, Daniel

Subjects

*THREE-dimensional imaging, *HYDROXIDES, *STORAGE rings, *OXONIUM ions, *ION beams, *CHEMICAL reactions, *CRYOGENICS, *ION bombardment

Abstract

Mutual neutralization of hydronium (H3O+) and hydroxide (OH−) ions is a very fundamental chemical reaction. Yet, there is only limited experimental evidence about the underlying reaction mechanisms. Here, we report three-dimensional imaging of coincident neutral products of mutual-neutralization reactions at low collision energies of cold and isolated ions in the cryogenic double electrostatic ion-beam storage ring (DESIREE). We identified predominant H2O + OH + H and 2OH + H2 product channels and attributed them to an electron-transfer mechanism, whereas a minor contribution of H2O + H2O with high internal excitation was attributed to proton transfer. The reported mechanism-resolved internal product excitation, as well as collision-energy and initial ion-temperature dependence, provide a benchmark for modeling charge-transfer mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024