17–22 Sept 2023
Asia/Seoul timezone

Identifying the Origin of Presolar Grains: Gamma-Spectroscopy of 35Ar

19 Sept 2023, 17:50
5m

Speaker

Ben REED (University of Surrey)

Description

Classical novae are the second most common explosive stellar phenomena in the Universe [1] and, as such, play an important role in the enrichment of the interstellar medium and chemical abundances we observe in the galaxy. One observable, which is key to understanding the processes that drive classical novae, is presolar grains. It is, therefore, important that we are able to characterise the origin of presolar grains based on their isotopic ratios. One issue that remains is being able to distinguish between grains of nova and supernova origin.

It has been suggested that the $^{34}$S/$^{32}$S isotopic ratio could be used, in conjunction with the well-known $^{33}$S/$^{32}$S ratio [2], in order to distinguish between solar and novae presolar grains [3,4]. The abundance of $^{34}$S is dependent on the $^{34g,m}$Cl(p,γ)$^{35}$Ar rp-process reaction rate. To determine this reaction rate, one has to know the energy, spin and parity of the contributing resonances in $^{35}$Ar. The energies of all states above the proton threshold have been measured [3], however, almost all the spins and parities remain unknown.

Here, we report a gamma-spectroscopy measurement of $^{35}$Ar with the aim of observing gamma decay from states above the proton-emission threshold. This experiment was conducted at Argonne National Laboratory’s ATLAS facility. States in 35Ar were populated via the $^{9}$Be($^{28}$Si,2 n)$^{35}$Ar fusion-evaporation reaction. The excited states decay via the emission of gamma rays, which are detected using Gammasphere, in coincidence with the recoils at the focal plane of the Fragment Mass Analyzer (FMA).

This measurement represents the first observation of gamma-decays from states above the proton threshold in $^{35}$Ar and led to more precise measurements of the resonance energies of the key states. The observed gamma-decay branches, along with mirror nuclei comparisons, enable restrictions to be placed on the spin-parity quantum numbers. This enables restrictions to be placed on the $^{34g,m}$Cl(p,γ)$^{35}$Ar reaction rate and the $^{34}$S/$^{32}$S isotopic ratio in novae.

[1] J. José, C. Iliadis, Reports on Progress in Physics 74, 096901 (2011)
[2] A. Parikh, et al., Phys. Lett. B 737, 314-319 (2014)
[3] C. Fry, et al., Phys. Rev. C 91 015803 (2015)
[4] A. R. L. Kennington et al., Phys. Rev. C 103, 035805 (2021)

Primary author

Ben REED (University of Surrey)

Co-authors

Dr Daniel DOHERTY (University of Surrey) Dr Dariusz SEWERYNIAK (Argonne National Laboratory) Prof. Gavin LOTAY (University of Surrey) Dr Helena ALBERS (GSI Helmholtz Centre for Heavy Ion Research) Dr Michael CARPENTER (Argonne National Laboratory) Dr Riley ILIEVA (University of Surrey) Prof. Robert JANSSENS (University of North Carolina) Dr Ryan WILKINSON (University of Surrey) Dr Shaofei ZHU (Argonne National Laboratory) Dr Torben LAURITSEN (Argonne National Laboratory)

Presentation materials

There are no materials yet.