Your search keyword '"D. Wolf Savin"' showing total 2 results

1. Exploring high-energy doubly excited states of NH by dissociative recombination of NH+

Author

C. Domesle, Henrik Buhr, D. Wolf Savin, Roland Repnow, Manfred Grieser, X. Cai, Christian Nordhorn, O. Novotny, M. B. Mendes, Wolf D. Geppert, Bian Yang, Dirk Schwalm, Florian Grussie, Andreas Wolf, Dennis Bing, Claude Krantz, and Max H. Berg

Subjects

Physics, Range (particle radiation), High energy, Hydrogen, Electron capture, chemistry.chemical_element, Quantendynamik - Abteilung Blaum, Condensed Matter Physics, Nitrogen, Molecular physics, Atomic and Molecular Physics, and Optics, chemistry, Excited state, Physics::Atomic Physics, Atomic physics, Dissociative recombination

Abstract

We have investigated electron capture by NH+ resulting in dissociative recombination (DR). The impact energies studied of ~4–12 eV extend over the range below the two lowest predicted NH+ dissociative states in the Franck–Condon (FC) region of the ion. Our focus has been on the final state populations of the resulting N and H atoms. The neutral DR fragments are detected downstream of a merged electron and ion beam interaction zone in the TSR storage ring, which is located at the Max Planck Institute for Nuclear Physics in Heidelberg, Germany. Transverse fragment distances were measured on a recently developed high count-rate imaging detector. The distance distributions enabled a detailed tracking of the final state populations as a function of the electron collision energy. These can be correlated with doubly excited neutral states in the FC region of the ion. At low electron energy of ~5 eV, the atomic product final levels are nitrogen Rydberg states together with ground-state hydrogen. In a small electron energy interval near 7 eV, a significant part of the final state population forms hydrogen Rydberg atoms with nitrogen atoms in the first excited (2D) term, showing the effect of Rydberg doubly excited states below the predicted 2 2Π ionic potential. The distance distributions above ~10 eV are compatible with nitrogen Rydberg states correlating to the doubly excited Rydberg state manifold below the ionic 2 4 Σ − level.

Published

2014

2. Deriving instrumental point spread functions from partially occulted images.

Author

Hofmeister SJ, Hahn M, and Wolf Savin D

Subjects

Phantoms, Imaging, Photons, Image Processing, Computer-Assisted methods, Algorithms

Abstract

The point spread function (PSF) of an imaging system describes the response of the system to a point source. Accurately determining the PSF enables one to correct for the combined effects of focusing and scattering within the imaging system and, thereby, enhance the spatial resolution and dynamic contrast of the resulting images. We present a semi-empirical semi-blind methodology to derive a PSF from partially occulted images. We partition the two-dimensional PSF into multiple segments, set up a multilinear system of equations, and directly fit the system of equations to determine the PSF weight in each segment. The algorithm is guaranteed to converge toward the correct instrumental PSF for a large class of occultations, does not require a predefined functional form of the PSF, and can be applied to a large variety of partially occulted images, such as within laboratory settings, regular calibrations within a production line or in the field, astronomical images of distant clusters of stars, or partial solar eclipse images. We show that the central weight of the PSF, which gives the percentage of photons that are not scattered by the instrument, is accurate to better than 1.2%. The mean absolute percentage error between the reconstructed and true PSF is usually between 0.5 and 5% for the entire PSF, between 0.5 and 5% for the PSF core, and between 0.5 and 3% for the PSF tail.

Published

2022