6533b871fe1ef96bd12d24cc
RESEARCH PRODUCT
Alternative approach to populate and study the $^{229}Th$ nuclear clock isomer
Shane WilkinsM. LaatiaouiStefaan CottenierIain MooreE. VerstraelenVladimir ManeaV. N. FedosseevC. GranadosS. GeldhofJanni MoensP. C. LinJ. G. CorreiaUlrich WahlRafael FerrerT. A. L. LimaB. A. MarshK. ChrysalidisAndré VantommeM. VerlindeL. M. FraileP. Van Den BerghLino Miguel Da Costa PereiraD. V. FedorovP. Van DuppenH. De WitteS. RaederS. Kraemersubject
Technology and EngineeringIon beamFOS: Physical sciencesNuclear isomernucl-ex7. Clean energy01 natural sciences010305 fluids & plasmasNuclear physicsRecoil0103 physical sciencesEXCITATIONRadiative transferNuclear Physics - Experimentddc:530Nuclear Experiment (nucl-ex)010306 general physicsLASER SPECTROSCOPYNuclear ExperimentNuclear ExperimentPhysicsnuclear structure and decaysAtomic clockChemistryPhysics and AstronomySTATESbeta decayGround stateisomer decaysydinfysiikkaDECAYEnergy (signal processing)ExcitationTRANSITIONdescription
A new approach to observe the radiative decay of the $^{229}$Th nuclear isomer, and to determine its energy and radiative lifetime, is presented. Situated at a uniquely low excitation energy, this nuclear state might be a key ingredient for the development of a nuclear clock, a nuclear laser and the search for time variations of the fundamental constants. The isomer's $\gamma$ decay towards the ground state will be studied with a high-resolution VUV spectrometer after its production by the $\beta$ decay of $^{229}$Ac. The novel production method presents a number of advantages asserting its competitive nature with respect to the commonly used $^{233}$U $\alpha$-decay recoil source. In this paper, a feasibility analysis of this new concept, and an experimental investigation of its key ingredients, using a pure $^{229}$Ac ion beam produced at the ISOLDE radioactive beam facility, is reported.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2019-04-23 |