High-precision Penning trap mass measurements of ‘difficult’ elements produced via projectile fragmentation with LEBIT

Rare isotope beams of many elements can be difficult or impossible to obtain at ISOL facilities due to their high melting points or chemical reactivity, but they are easily produced by projectile fragmentation and in-flight separation, a technique that rapidly produces fragments lighter than the pro...

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Bibliographic Details
Published in:Hyperfine interactions 2011, Vol.199 (1-3), p.251-259
Main Authors: Ringle, R., Bachelet, C., Barquest, B. R., Block, M., Bollen, G., Campbell, C. M., Facina, M., Ferrer, R., III, C. M. Folden, Guénaut, C., Kwan, E., Kwiatkowski, A. A., Lincoln, D. L., Morrissey, D. J., Pang, G. K., Prinke, A. M., Savory, J., Schury, P., Schwarz, S., Sumithrarachchi, C. S.
Format: Article
Language:English
Subjects:
Atomic
Condensed Matter Physics
Hadrons
Heavy Ions
Molecular
Nuclear Physics
Optical and Plasma Physics
Physics
Physics and Astronomy
Surfaces and Interfaces
Thin Films
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Summary:Rare isotope beams of many elements can be difficult or impossible to obtain at ISOL facilities due to their high melting points or chemical reactivity, but they are easily produced by projectile fragmentation and in-flight separation, a technique that rapidly produces fragments lighter than the projectile in a chemistry-free manner. Until recently, such high-energy projectile fragments could not be reduced to the thermal energies necessary for precision mass measurements in Penning traps. The Low Energy Beam and Ion Trap (LEBIT) facility at the National Superconducting Cyclotron Laboratory (NSCL) has demonstrated that projectile fragment beams can be thermalized and measured in a high-precision Penning trap. Since 2005, over 30 isotopes have been measured with LEBIT, including several isotopes of elements which are difficult for ISOL facilities to produce, such as Fe, Co, Si, Br, and S. These measurements have contributed to our understanding of nuclear structure, nuclear astrophysics, and fundamental symmetries. Some recent highlights include the discovery of an isomeric state in 65 Fe, testing the Isobaric Mass Multiplet Equation (IMME) with the A  =  32, T  =  2 quintet with a measurement of 32 Si, probing out to the proton dripline with 70 m Br, and studying the N  =  28 shell closure with measurements of 40 − 44 S. Results of these measurements will be discussed, along with the technical developments which made them possible.
ISSN:0304-3843
1572-9540
DOI:10.1007/s10751-011-0320-x