Overview
Background
Jacinda Ginges is a theoretical physicist in the School of Mathematics and Physics at UQ. Her research is directed towards atomic tests of fundamental physics, involving development and application of high-precision many-body methods for heavy atoms. Her areas of expertise include high-precision studies of fundamental symmetries violations (parity, time) and probes of nuclear structure. Atomic parity violation studies provide some of the tightest constraints on possible new physics beyond the standard model of particle physics, complementing searches for new physics at the LHC and dark matter searches. Studies of parity- and time-reversal-violating atomic electric dipole moments tightly constrain possible new sources of CP-violation appearing in theories beyond the standard model.
Positions:
- 2024- Associate Professor, The University of Queensland, Australia
- 2018- Senior Lecturer, The University of Queensland, Australia
- 2018-2022 ARC Future Fellow, The University of Queensland, Australia
- 2017 Research Fellow, ARC Centre of Excellence for Engineered Quantum Systems, The University of Sydney, Australia
- 2014-2016 Senior Research Associate, UNSW Sydney, Australia
- 2004-2008 ARC Australian Postdoctoral Fellow and Lecturer, UNSW Sydney, Australia
- 2004 Avadh Bhatia Postdoctoral Fellowship for Women, University of Alberta, Canada
Availability
- Associate Professor Jacinda Ginges is:
- Available for supervision
Fields of research
Qualifications
- Doctor of Philosophy, University of New South Wales
Research interests
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High-precision atomic many-body theory
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Quantum electrodynamics corrections to heavy-atom phenomena
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Violations of fundamental symmetries
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Precision tests of the standard model of particle physics and searches for new physics
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Superheavy elements
Works
Search Professor Jacinda Ginges’s works on UQ eSpace
2016
Journal Article
Atomic many-body effects and Lamb shifts in alkali metals
Ginges, J. S. M. and Berengut, J. C. (2016). Atomic many-body effects and Lamb shifts in alkali metals. Physical Review A, 93 (5) 052509. doi: 10.1103/PhysRevA.93.052509
2016
Journal Article
QED radiative corrections and many-body effects in atoms: vacuum polarization and binding energy shifts in alkali metals
Ginges, J. S. M. and Berengut, J. C. (2016). QED radiative corrections and many-body effects in atoms: vacuum polarization and binding energy shifts in alkali metals. Journal of Physics B: Atomic Molecular and Optical Physics, 49 (9) 095001, 095001. doi: 10.1088/0953-4075/49/9/095001
2015
Journal Article
Spectra of barium, radium, and element 120: application of the combined correlation-potential, singles-doubles, and configuration-interaction ab initio methods
Ginges, J. S. M. and Dzuba, V. A. (2015). Spectra of barium, radium, and element 120: application of the combined correlation-potential, singles-doubles, and configuration-interaction ab initio methods. Physical Review A, 91 (4) 042505. doi: 10.1103/PhysRevA.91.042505
2011
Journal Article
Atomic electric dipole moment induced by the nuclear electric dipole moment: the magnetic moment effect
Porsev, S. G., Ginges, J. S. M. and Flambaum, V. V. (2011). Atomic electric dipole moment induced by the nuclear electric dipole moment: the magnetic moment effect. Physical Review A, 83 (4) 042507. doi: 10.1103/PhysRevA.83.042507
2010
Journal Article
Glimpses of Science: Multi-media enhanced hands-on learning activities for primary school students
Hatsidimitris, George, Connor, Rick, Ginges, Jacinda and Wolfe, Joe (2010). Glimpses of Science: Multi-media enhanced hands-on learning activities for primary school students. Teaching Science, 56, 39-42.
2008
Journal Article
Calculation of the spectrum of the superheavy element Z=120
Dinh, T. H., Dzuba, V. A., Flambaum, V. V. and Ginges, J. S. M. (2008). Calculation of the spectrum of the superheavy element Z=120. Physical Review A, 78 (5) 054501. doi: 10.1103/PhysRevA.78.054501
2008
Journal Article
Calculations of the spectra of superheavy elements Z=119 and Z= 120+
Dinh, T. H., Dzuba, V. A., Flambaum, V. V. and Ginges, J. S. M. (2008). Calculations of the spectra of superheavy elements Z=119 and Z= 120+. Physical Review A, 78 (2) 022507. doi: 10.1103/PhysRevA.78.022507
2007
Journal Article
Atomic electric dipole moments of He and Yb induced by nuclear Schiff moments
Dzuba, V. A., Flambaum, V. V. and Ginges, J. S. M. (2007). Atomic electric dipole moments of He and Yb induced by nuclear Schiff moments. Physical Review a, 76 (3) 034501 doi: 10.1103/PhysRevA.76.034501
2006
Journal Article
Calculations of energy levels and lifetimes of low-lying states of barium and radium
Dzuba, V. A. and Ginges, J. S. M. (2006). Calculations of energy levels and lifetimes of low-lying states of barium and radium. Physical Review A, 73 (3) 032503. doi: 10.1103/PhysRevA.73.032503
2006
Conference Publication
Theoretical issues in parity and time-reversal violation in atoms
Ginges, Jacinda (2006). Theoretical issues in parity and time-reversal violation in atoms. Annual Meeting of the Division of Particles and Fields of the American Physical Society, DPF 2006, and the Annual Fall Meeting of the Japan Particle Physics Community, , , October 30, 2006-November 3, 2006. American Physical Society.
2006
Journal Article
Resonance reactions and enhancement of weak interactions in collisions of cold molecules
Flambaum, V. V. and Ginges, J. S. M. (2006). Resonance reactions and enhancement of weak interactions in collisions of cold molecules. Physical Review a, 74 (2) 025601. doi: 10.1103/PhysRevA.74.025601
2005
Conference Publication
Status of parity violation in cesium
Ginges, Jacinda (2005). Status of parity violation in cesium. Nineteenth Lake Louise Winter Institute: Fundamental Interactions, Lake Louise, Canada, 15-21 February 2004. Hackensack, USA: World Scientific.
2002
Journal Article
Electric dipole moments of Hg, Xe, Rn, Ra, Pu, and TlF induced by the nuclear Schiff moment and limits on time-reversal violating interactions
Dzuba, V. A., Flambaum, V. V., Ginges, J. S. M. and Kozlov, M. G. (2002). Electric dipole moments of Hg, Xe, Rn, Ra, Pu, and TlF induced by the nuclear Schiff moment and limits on time-reversal violating interactions. Physical Review A, 66 (1) 012111, 121111-121117. doi: 10.1103/PhysRevA.66.012111
2001
Journal Article
Calculations of parity-nonconserving s-d amplitudes in Cs, Fr, Ba+, and Ra+
Dzuba, V. A., Flambaum, V. V. and Ginges, J. S.M. (2001). Calculations of parity-nonconserving s-d amplitudes in Cs, Fr, Ba+, and Ra+. Physical Review A. Atomic, Molecular, and Optical Physics, 63 (6)
2001
Conference Publication
Electric field distribution in nuclei produced by the P,T-odd nuclear Schiff moment
Flambaum, VV and Ginges, JSM (2001). Electric field distribution in nuclei produced by the P,T-odd nuclear Schiff moment. ComminsFest Symposium on Art and Symmetry in Experimental Physics, Berkeley Ca, May 20-21, 2001. AMER INST PHYSICS. doi: 10.1063/1.1426805
2001
Journal Article
Calculations of parity-nonconserving [Formula Presented] amplitudes in Cs, Fr, [Formula Presented] and [Formula Presented]
Dzuba, VA, Flambaum, VV and Ginges, JSM (2001). Calculations of parity-nonconserving [Formula Presented] amplitudes in Cs, Fr, [Formula Presented] and [Formula Presented]. Physical Review a, 63 (6) 062101 doi: 10.1103/PhysRevA.63.062101
2000
Conference Publication
Enhancement of parity and time invariance violation in heavy atoms
Dzuba, VA, Flambaum, VV and Ginges, JSM (2000). Enhancement of parity and time invariance violation in heavy atoms. 3rd International Symposium on Symmetries in Subatomic Physics (SYMM 2000), Adelaide Australia, Mar 13-17, 2000. AMER INST PHYSICS. doi: 10.1063/1.1330912
2000
Journal Article
Calculation of parity and time invariance violation in the radium atom
Dzuba, VA, Flambaum, VV and Ginges, JSM (2000). Calculation of parity and time invariance violation in the radium atom. Physical Review a, 61 (6), 062509-062501. doi: 10.1103/PhysRevA.61.062509
Supervision
Availability
- Associate Professor Jacinda Ginges is:
- Available for supervision
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Available projects
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PhD and Honours projects available.
Several PhD projects are available in our group. Some may be offered also as Honours projects. These projects are in the area of precision atomic theory and they lie at the interface of atomic, nuclear, and particle physics. They include:
- Tests of the standard model of particle physics and searches for new physics at the precision frontier. This includes calculations of atomic parity violation (APV) and time-reversal-violating electric dipole moments (EDMs) for interpretation of precision atomic experiments. Studies of violations of fundamental symmetries in atoms provide some of the most precise tests of the standard model, and they can help to answer some of the big questions of science, including: why is there a dominance of matter over antimatter in our Universe? What is the nature of dark matter? Atomic calculations are needed to interpret precision measurements in terms of fundamental particle physics parameters. It remains a challenge to increase the accuracy of calculations in order to maximise the discovery potential of atomic experiments, and this is a focus of our group.
- Development of precision atomic structure theory in heavy atoms. This includes development of all-orders atomic many-body methods and computer codes, and the combination of quantum electrodynamics and many-body theory. Improving the accuracy and capability of state-of-the-art atomic precision theory for heavy atoms is important for a number of different areas, including in studies of violations of fundamental symmetries (APV and EDMs), in probing the structure of the nucleus, in the study of the physical properties of heavy and superheavy elements, and in metrology including atomic clocks.
- Probing nuclear structure through precision atomic physics. Details of the structure of the nucleus may be revealed in precision studies of the hyperfine structure (HFS) in atoms. Studies of the HFS play an important role in nuclear and atomic physics, as well as in metrology. Indeed, the hyperfine splitting in the ground state of atomic Cs has been measured very precisely, and it defines the unit for time, the second. Comparison of theoretical and measured values of the HFS allows one to probe the structure of the nucleus and the quality of the atomic wave functions in the nuclear region. Our interest in this area is mulit-faceted, and we are devising new ways to better probe and model nuclear magnetic structure in heavy atoms.
- We have other projects available in our group, including studies of the properties of the superheavy elements — those with Z > 104, up to and beyond the heaviest elements of the Periodic Table — and in the area of metrology, in particular atomic clocks.
For further enquiries, please contact Dr. Ginges, j.ginges@uq.edu.au .
Supervision history
Current supervision
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Doctor Philosophy
Searching for new physics in precision atomic experiments
Principal Advisor
Other advisors: Dr Benjamin Roberts
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Doctor Philosophy
Probing and modelling nuclear structure for BSM searches in atoms and molecules
Principal Advisor
Other advisors: Dr Benjamin Roberts
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Doctor Philosophy
High-precision atomic theory and searches for new physics
Principal Advisor
Other advisors: Dr Benjamin Roberts
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Doctor Philosophy
Tests of fundamental physics in atoms
Principal Advisor
Other advisors: Dr Benjamin Roberts
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Doctor Philosophy
Atomic physics as a low-energy probe of the Standard Model
Associate Advisor
Other advisors: Dr Benjamin Roberts
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Doctor Philosophy
Exploring possibilities for dark matter detection via atomic interactions
Associate Advisor
Other advisors: Dr Benjamin Roberts
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Doctor Philosophy
Exploring possibilities for dark matter detection via atomic interactions
Associate Advisor
Other advisors: Dr Benjamin Roberts
Completed supervision
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2023
Doctor Philosophy
Simplified Models of New Physics with Dark Matter in GAMBIT
Principal Advisor
Media
Enquiries
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