Nuclear Structure and Reactions: Theory and Experiment

Lead Research Organisation: University of Brighton
Department Name: Sch of Computing, Engineering & Maths

Abstract

Nuclear physics research is undergoing a transformation. For a hundred years, atomic nuclei have been probed by collisions between stable beams and stable targets, with just a small number of radioactive isotopes being available. Now, building on steady progress over the past 20 years, it is at last becoming possible to generate intense beams of a wide range of short-lived isotopes, so-called 'radioactive beams'. This enables us vastly to expand the scope of experimental nuclear research. For example, it is now realistic to plan to study in the laboratory a range of nuclear reactions that take place in exploding stars. Thereby, we will be able to understand how the chemical elements that we find on Earth were formed and distributed through the Universe. At the core of our experimental research is our strong participation at leading European radioactive-beam facilities: FAIR at GSI, Darmstadt, Germany; SPIRAL at GANIL, Caen, France; and ISOLDE at CERN, Geneva, Switzerland. While we are now contributing, or planning to contribute, to substantial technical developments at these facilities, the present grant request is focused on the exploitation of the capabilities that are now becoming available. To achieve our physics objectives, we also need to use other facilities, including stable-isotope accelerators, since these can provide complementary capabilities. Experimental progress is intimately linked with theory, where novel and practical approaches are a hallmark of the Surrey group. A key and unique feature (within the UK) of our group is our blend of theoretical and experimental capability. Our science goals are aligned with current STFC strategy for nuclear physics, as expressed in detail through the Nuclear Physics Advisory Panel. We wish to understand the boundaries of nuclear existence, i.e. the limiting conditions that enable neutrons and protons to bind together to form nuclei. Under such conditions, the nuclear system is in a delicate state and shows unusual phenomena. It is very sensitive to the properties of the nuclear force. For example, weakly bound neutrons can orbit their parent nucleus at remarkably large distances. This is already known, and our group made key contributions to this knowledge. What is unknown is whether, and to what extent, the neutrons and protons can show different collective behaviours. Also unknown, for most elements, is how many neutrons can bind to a given number of protons. It is features such as these that determine how stars explode. So, we need a more sophisticated understanding of the nuclear force, and we need experimental information about nuclei with unusual combinations of neutrons and protons to test our theoretical ideas and models. Therefore, theory and experiment go hand-in-hand as we push forward towards the nuclear limits. An overview of nuclear binding reveals that about one half of predicted nuclei have never been observed, and the vast majority of this unknown territory involves nuclei with an excess of neutrons. The focus of our activity addresses this 'neutron-rich' territory, exploiting the new capabilities with radioactive beams. Our principal motivation is the basic science, and we contribute strongly to the world sum of knowledge and understanding. Nevertheless, there are more-tangible benefits. For example, our radiation-detector advances can be incorporated in medical diagnosis and treatment. In addition, we provide an excellent training environment for our research students and staff, many of whom go on to work in the nuclear power industry, helping to fill the current skills gap. On a more adventurous note, our special interest in nuclear isomers (energy traps) could lead to novel energy applications. Furthermore, we have a keen interest in sharing our specialist knowledge with a wide audience, and we already have an enviable track record with the media.

Publications

10 25 50

publication icon
Browne F (2023) Interpretation of metastable states in the $$N>70$$ Zr region in The European Physical Journal A

publication icon
Browne F (2015) Gamma-ray Spectroscopy in the Vicinity of $^{108}$Zr in Acta Physica Polonica B

publication icon
Bucurescu D (2016) The ROSPHERE ?-ray spectroscopy array in Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

 
Description We have measured the shape of some neutron-rich zirconium nuclei (Zr104 and Zr106).
The results have been compared with the shapes calculated by state-of-the-art models.
Our results will be used to modify and refine the models.
Exploitation Route Our results will be used to modify and refine state-of-the-art models. This was the first experiment using an array of lanthanum bromide detectors at a fragmentation facility.
Many other experiments which use the technique are now being planned.
Sectors Energy

URL https://www.brighton.ac.uk/research-and-enterprise/research/life-health-and-physical-sciences/research-groups/nuclear-physics/fission-fragments-produced-in-the-relativistic-fission-of-238u.aspx
 
Description University of Brighton, PhD studentship
Amount £50,000 (GBP)
Organisation University of Brighton 
Sector Academic/University
Country United Kingdom
Start 09/2009 
End 03/2013
 
Description Computer codes used to generate a 3-D model of a bicycle with a rider, and transform it to show a view as expected in the Special theory of Relativity accounting for the "Terrell Rotation" distortions. Fortran program does creation of bike and distortions. Python code post-processes output of Fortran code to include doppler effect and intensity beaming. 
Type Of Technology Software 
Year Produced 2019 
Open Source License? Yes  
URL https://surrey.figshare.com/articles/software/Gamow_s_Bike_Relativistic_Transformation_Code/8337056