AI Article Synopsis
- - Measurement of proton spectra is crucial for high energy density physics experiments, but existing diagnostics struggle with low-energy protons and high debris scenarios.
- - A new compact magnetic spectrometer called MagSpec was created to specifically measure proton spectra in the 1-20 MeV range, focusing on the low-energy range of 1-6 MeV for use at facilities like OMEGA and NIF.
- - The MagSpec works by dispersing protons of various energies through a magnetic field, allowing for a spatial distribution of CR-39 tracks that reflects the energy spectrum, and the paper details its design and implementation.
Article Abstract
Measurement of proton spectra is an important diagnostic for a variety of high energy density physics experiments. Current diagnostics are either not designed to capture the spectrum of low-energy protons or are unsuitable for high debris experiments. To bridge the gap, a new CR-39 based compact magnetic spectrometer (MagSpec) has been developed to measure proton spectra in the 1-20 MeV energy range, with a particular focus on the low-energy (1-6 MeV) spectrum, for use in experiments at the OMEGA Laser Facility and the National Ignition Facility (NIF). In the MagSpec diagnostic, protons of different energies are dispersed as they pass through a magnetic field before impinging on a differentially filtered CR-39 surface, resulting in a spatial distribution of CR-39 tracks that corresponds to the energy spectrum. In this paper, we discuss details of the design and implementation of MagSpec on the NIF and OMEGA.
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| http://dx.doi.org/10.1063/5.0219482 | DOI Listing |
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