Statistical properties of 133Xe and the 132Xe(n,γ) cross section

Abstract

133Xe is an interesting case for plasma physics to explore nuclear excitation by electron capture, as the process can be studied using statistical properties of 133Xe. In this work we present results on 133Xe from the inverse-Oslo method where we extract the nuclear level density and the γ-strength function, which is used to calculate the (n,γ) cross section on 132Xe. The γ-strength function of 133Xe can constrain the estimated decay rate from nuclear excitation by electron capture. The d(132Xe,p)132Xe reaction was used to create the compound nucleus 133Xe, which was recorded with an annular particle telescope and a scintillator array consisting of and BGO-shielded HPGe Clover detectors. With the inverse-Oslo method, it is possible to study nuclei that are impossible or unable to manufacture targets from, short lived isotopes, or as in this work, noble gases. We present the extracted nuclear level density, and γ-strength function for 133Xe, along with shell-model calculations of the statistical properties of 133Xe. These are the first statistical properties extracted below 6 MeV for any xenon isotope. We constrain the 132Xe(n,γ) 133Xe cross section and reaction rate using the TALYS reaction code.