Search for toroids in excited nuclear material

A. Hannaman; B. Harvey; A.B. McIntosh; K. Hagel; L. Bills; A. Abbott; A. Fentress; J. Gauthier; T. Hankins; Y.-W. Lui; L. Bills; L.A. McIntosh; S. Regener; R. Rider; S. Schultz; M.Q. Sorensen; J. Tobar; Z. Tobin; S. Yennello

doi:10.1051/epjconf/202430401001

All issues

Volume 304 (2024)

EPJ Web Conf., 304 (2024) 01001

Abstract

Open Access

Issue		EPJ Web Conf. Volume 304, 2024 HINPw7 – 7^th International Workshop of the Hellenic Institute of Nuclear Physics on Nuclear Structure, Astrophysics and Reaction Dynamics


Article Number		01001
Number of page(s)		4
Section		Reaction Dynamics
DOI		https://doi.org/10.1051/epjconf/202430401001
Published online		08 October 2024

EPJ Web of Conferences 304, 01001 (2024)
https://doi.org/10.1051/epjconf/202430401001

Search for toroids in excited nuclear material

A. Hannaman¹^,2, B. Harvey¹^,3, A.B. McIntosh¹, K. Hagel¹, L. Bills¹^,2, A. Abbott¹^,2, A. Fentress¹^,2, J. Gauthier¹, T. Hankins¹^,2, Y.-W. Lui¹, L. Bills¹^,2, L.A. McIntosh¹, S. Regener¹, R. Rider¹^,2, S. Schultz¹^,2, M.Q. Sorensen¹^,2, J. Tobar¹^,2, Z. Tobin¹^,2 and S. Yennello¹^,2^*

¹ Cyclotron Institute, Texas A&M University, College Station, TX 77843, USA
² Department of Chemistry, Texas A&M University, College Station, TX 77843, USA
³ Department of Physics, Texas A&M University, College Station, TX 77843, USA

^* e-mail: yennello@tamu.edu

Published online: 8 October 2024

Abstract

Ground state nuclei usually have compact geometries. However, there have been theoretical predictions that excited nuclei can take on more extended shapes such as toroids or bubbles. There have been many attempts to identify signatures of such shapes in experimental data. One signature, both predicted by theory and reported in experimental data, is narrow resonances at high excitation energy in peripheral intermediate-energy heavy-ion collisions. This potential evidence for toroidal states was reported in the alpha particle disassembly of ²⁸Si after collision with a ¹²C target at 35 MeV/nucleon. The prior work was limited by angular resolution and statistical uncertainties. The present work aims to measure the excitation energy distribution for these disassembly events with improved angular resolution and reduced statistical uncertainty using the Forward Array Using Silicon Technology (FAUST). FAUST is equipped with resistive dual-axis duo-lateral (DADL) position-sensitive silicon detectors capable of sub-millimeter position resolution. The measured excitation energy distributions of 7-α disassembly events showed no strong evidence for highly excited states at the cross section and widths suggested by previous experiment.

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