Your search keyword '"B. Wiegel"' showing total 3 results

1. Comparison of measured cosmic ray LET spectra with models and predictions.

Author

Heinrich W, Benton EV, Wiegel B, Rusch G, and Becker E

Subjects

Forecasting, Mathematics, Plastics, Polyethylene Glycols, Solar Activity, Cosmic Radiation, Linear Energy Transfer, Models, Theoretical, Protons, Radiation Monitoring instrumentation, Radiometry instrumentation, Space Flight instrumentation

Abstract

Radiation effects of cosmic ray nuclei are generally described as a function of the particle LET. For a large number of space missions LET spectra have been measured and models have been developed to calculate these spectra that include the effects of geomagnetic shielding and shielding provided by material. In this paper we compare measured and calculated LET spectra. For low earth orbits events with high local energy deposition, i.e., short range secondaries, contribute significantly to the measured spectra. These events are produced by nuclear interactions, mainly induced by protons from the south atlantic anomaly. The technique to include these contributions in the models depends on the size of radiation sensitive volumes. For sizes comparable to or larger than the range of target secondaries it is essential to separate contributions by target interactions from those of cosmic rays. This separation is possible in experiments which use stacks of plastic nuclear track detectors. The yield of short range events generated by protons and measured in the detector can be calibrated from accelerator experimental data. We present first results for CR-39 detectors.

Published

1994

2. Galactic cosmic ray abundances and spectra behind defined shielding.

Author

Heinrich W, Benton EV, Wiegel B, Zens R, and Rusch G

Subjects

Magnetics, Solar Activity, Spacecraft instrumentation, Spectrum Analysis, Cosmic Radiation, Linear Energy Transfer, Models, Theoretical, Radiation Protection, Radiometry, Space Flight instrumentation

Abstract

LET spectra have been measured for lunar missions and for several near Earth orbits ranging from 28 degrees to 83 degrees inclination. In some of the experiments the flux of GCR was determined separately from contributions caused by interactions in the detector material. Results of these experiments are compared to model calculations. The general agreement justifies the use of the model to calculate GCR fluxes. The magnitude of variations caused by solar modulation, geomagnetic shielding, and shielding by matter determined from calculated LET spectra is generally in agreement with experimental data. However, more detailed investigations show that there are some weak points in modeling solar modulation and shielding by material. These points are discussed in more detail.

Published

1994

3. Measurements of LET spectra and comparison to models.

Author

Wiegel B, Heinrich W, Benton EV, and Frank A

Subjects

Extraterrestrial Environment, Protons, Radiation Protection statistics & numerical data, Cosmic Radiation, Linear Energy Transfer, Models, Theoretical, Radiation Monitoring statistics & numerical data, Space Flight

Abstract

We present measurements of LET spectra for near earth orbits with various inclinations and altitudes. A comparison with calculated LET spectra shows that the contribution from direct ionizing galactic cosmic rays is well described by the models. An additional contribution to the spectra originates from stopping protons and from nuclear interactions of particles with material. In the case of an interaction a large amount of energy is deposited in a small volume by target recoils or target fragments. These events will be called short range (SR) events. For a low inclination orbit radiation belt protons are the main source of these events while galactic protons become more important when increasing the inclination to near polar orbits. We show that the contribution of SR events for orbits with low altitude (324 km) and 57 degrees inclination is comparable to that for an orbit with 28 degrees inclination at a high altitude (510 km).

Published

1992