The first early career researcher (ECR) forum for UK nuclear physics will be held in-person at the Institute of Physics building in London on the 1st and 2nd of November, 2021. This is an opportunity for early-career scientists to gather and discuss the research that they would like to pursue over the next decade. A career development panel will also be convened, featuring members of fellowship and funding advisory groups - an excellent chance for ECRs to gather information for future proposals.
This will be an inclusive event and there will be no registration fee for attending. If you consider yourself to be an early career researcher, you are welcome to attend. We do not currently anticipate the need to limit the number of attendees, however if this situation changes we will prioritise the in-person attendance of PDRAs.
In the coming months we will invite submissions to present at the forum, and encourage you to think now about topics you wish to be covered, as well as your future scientific goals/interests. We want to particularly focus on the future: the more speculative, the better.
The Recoil Distance Doppler-Shift (RDDS) method for measuring the lifetime of excited nuclear states relies on the detection of
The charge plunger method has recently been used at the University of Jyvaskyla Accelerator Laboratory, Finland, to perform lifetime measurements of yrast states in
[1] Ulfert, G., Habs, D., Metag, V., and Specht, H., Nuc. Instr. and Meth. 148 (1978) 369 .
[2] Carlson, T., Hunt, W., and Krause, M., Phys. Rev. 151 (1966) 41.
[3] Schiwietz, G. and Grande, P., Nuc. Instr. and Meth. in Phys. Res. B 175 (2001) 125.
[4] Barber, L. et al., Nuc. Instr. and Meth. in Phys. Res. A 979 (2020) 164454.
[5] Heery, J. et al., Eur. Phys. Jour. A 57 (2021).
Quantum Chromo Dynamics (QCD), the theory describing the strong force, predicts how quarks and gluons form into hadrons. Although all established meson and baryon states are either quark-anti quark pairs or three (anti)quark states, QCD also allows for combinations of four or more quarks. In addition, states in which gluons are excited and contribute to the quantum numbers of the hadrons are also possible. Jefferson Lab, with its GlueX experiment, is one of the prime facilities to hunt for these exotic particles.
In this talk I will introduce the open questions around exotic hadrons and present some of the ongoing efforts at Jefferson Lab. In addition, I will present how a future Electron-Ion Collider, currently in its planning stage, will provide us with opportunities to study these states in unprecedented detail.
Interpretations of the collective behaviour of nuclei have long been dependent on our understanding of E2 nuclear matrix elements. Owing to mastery of the electromagnetic force and it’s spherical tensor we claim confident in quadrupole properties of the nucleus. Despite this confidence there are frequent discrepancy in assignments often owing to interpretations made with incomplete information.
As we look more frequently at the interpretation of shape coexistence across a broader swathe of the nuclear chart, E0 matrix elements have become a key observable in our experiments.
However in contrast to E2 matrix elements, our interpretations of E0 transitions are often flawed and inconsistent, and theoretical models frequently fail to reproduce E0 strength. A greater wealth of knowledge and detailed study is clearly required.
In this talk I will highlight the current state on E0 knowledge in the field, discuss some recent interesting E0 measurement and present some early concept ideas for a future electron spectrometer.
The Electrons for Neutrinos project (e4nu) at the Thomas Jefferson National Accelerator Facility (JLab) uses wide phase space exclusive electron scattering data from past and future experiments on nuclear targets with the CLAS and CLAS12 detector systems to obtain a comprehensive understanding of the interaction of leptons with matter. Data from JLab provides us with the means to constrain the available theoretical tools that are crucial in modelling the neutrino-nucleus interaction, and thus play a key role in the precise determination of the physics observables from neutrino-nucleus interactions measured at current and future neutrino experimental facilities, including MicroBooNE, MINERvA, DUNE and T2K.
The interdisciplinary nature of the e4nu project has brought new insights to older data, establishing the value of data mining efforts at JLab, and motivating new experiments, including a dedicated e4nu run period with the CLAS12 detector. Starting this autumn, we will take data with 1, 2, 4, and 6 GeV beams, on Deuterium, Oxygen, Carbon and Argon targets, greatly expanding the available data. Coupled with neutrino event generator descriptions of various reaction topologies, and a common analysis framework, e4nu can serve as a prime example of how to motivate future experiments and build new collaborations.
The MARA low-energy branch (MARA-LEB) [1] is a novel facility currently under development at the University of Jyväskylä. The primary aim of MARA-LEB will be to study ground and isomeric-state properties of exotic proton-rich nuclei employing in-gas-cell and in-gas-jet resonance ionisation spectroscopy and mass measurements. Initially these studies will focus on nuclei close to the N=Z line and in the region of 100Sn which are of particular interest to the astrophysical rp process [2] and the study of the proton-neutron interaction [3], before expanding to other regions of the nuclear chart.
For the study of exotic nuclei, special experimental conditions are required to isolate the ions of interest from the overwhelming amount of unwanted nuclei produced during nuclear reactions. In MARA-LEB these conditions will be achieved by combining the MARA vacuum-mode mass separator [4,5] with a buffer gas cell, an ion guide system [6] and a dipole mass separator for stopping, thermalising and transporting reaction products to the experimental stations.
Resonance laser ionisation spectroscopy will be possible either in a separate region inside the gas cell or inside a hypersonic gas jet at the exit of the cell, which will allow for more accurate measurements [7]. A dedicated state-of-the-art Ti:Sapphire laser system will be used to provide reliable experimental data on the ground and isomeric-state properties of exotic isotopes.
Mass measurements will be achieved using a radiofrequency quadrupole cooler and buncher coupled to a multi-reflection time-of-flight mass spectrometer [8]. These devices will allow for fast and accurate mass measurements of several isotopes with high impact on the rp process or isotopes which can be used as test grounds for state-of-the-art nuclear models.
A dedicated high-efficiency decay station, in combination with the low-background ion signals available after laser ionisation or mass purification, will provide ideal conditions for detailed decay studies of the nuclei of interest.
In this presentation I will give an overview of the MARA-LEB facility and some of the key science cases, and present the outcome of preliminary tests.
[1] P. Papadakis et al., Hyperfine Interact 237:152 (2016).
[2] R.K. Wallace and S.E. Woosley, Astrophys. J. Suppl. Ser. 45, 389 (1981).
[3] S. Frauendorf and A.O. Macchiavelli, Prog. in Part. and Nucl. Phys. 78, 24 (2014).
[4] J. Sarén, PhD thesis, University of Jyväskylä (2011).
[5] J. Uusitalo et al., Acta Phys. Pol. B 50, 319 (2019).
[6] P. Papadakis et al., Nucl. Instr. and Meth. B 463, 286 (2020).
[7] R. Ferrer et al., Nature comm. 8, 14520 (2017).
[8] R.N. Wolf et al., Nucl. Instr. and Meth. A 686, 82 (2012).
After joining Sheffield Hallam University (SHU) in 2017, Robin Smith has grown a small nuclear physics group, which now includes three PhD students, who are working on a variety of topics, spanning nuclear structure, astrophysics, nuclear data, and fusion.
This talk will give a brief overview of some of the research that is happening in nuclear physics at SHU, with a focus on searches for unambiguous signatures of alpha particle clustering, and developing new techniques for nuclear astrophysics. It will also cover the facilities used, funding, and will give an outlook for the next few years.