Production and identification of100Sn

Schneider, Roland; Friese, J.; Reinhold, J.; Zeitelhack, K.; Faestermann, T.; Gernhäuser, R.; Gilg, H. Albert; Heine, F.; Homolka, J.; Kienle, Paul; Körner, H. J.; Geißel, H.; Münzenberg, G.; Sümmerer, K.

doi:10.1007/bf01305875

Cited by 137 publications

(39 citation statements)

References 5 publications

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“…In such experiments dedicated to explore the limits of presently known nuclei the full particle identification and often the production cross section have been published [16,17]. More information is gained, if first decay properties are deduced as well.…”

Section: Identification and Investigation Of New Isotopes With Time-rmentioning

confidence: 99%

Discovery and investigation of heavy neutron-rich isotopes with time-resolved Schottky spectrometry in the element range from thallium to actinium

et al. 2010

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Section: Identification and Investigation Of New Isotopes With Time-rmentioning

confidence: 99%

Discovery and investigation of heavy neutron-rich isotopes with time-resolved Schottky spectrometry in the element range from thallium to actinium

et al. 2010

Self Cite

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“…Fragmentation reactions are widely used in rare-ionbeam facilities based on the in-flight separation technique for producing nuclei far from stability [1,2]. Indeed, this reaction mechanism contributed significantly to enlarge the present limits of the chart of nuclides reaching the proton drip-line up to mercury [3].…”

Section: Introductionmentioning

confidence: 99%

Production of neutron-rich nuclei in fragmentation reactions of Sn132 projectiles at relativistic energies

Pérez–Loureiro¹,

Benlliure²,

Álvarez‐Pol³

et al. 2011

Physics Letters B

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The fragmentation of neutron-rich 132 Sn nuclei produced in the fission of 238 U projectiles at 950 MeV/u has been investigated at the FRagment Separator (FRS) at GSI. This work represents the first investigation of fragmentation of medium-mass radioactive projectiles with a large neutron excess. The measured production cross sections of the residual nuclei are relevant for the possible use of a two-stage reaction scheme (fission+fragmentation) for the production of extremely neutron-rich medium-mass nuclei in future rare-ion-beam facilities. Moreover, the new data will provide a better understanding of the "memory" effect in fragmentation reactions.

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“…Key contributions from GSI were the production of the heaviest elements known today [1,2] with Z = 107 to 112, the discovery of the proton radioactivity from the ground state [3] and the first observation of the doubly magic nuclei [4,5] 100 Sn and 78 Ni. A region covering more than hundred new masses was measured with high precision.…”

Section: -Introductionmentioning

confidence: 99%

Perspectives for nuclear structure research at GSI—from halo nuclei to superheavy elements

Münzenberg

1997

Nuov Cim A

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Summary.-After a brief overview on recent advances in the investigation of nuclei at the driplines and the upper end of the nuclear table key issues of nuclear structure research as addressed by new theoretical developments will be discussed in context with new developments in heavy-ion accelerators and experimental techniques.PACS 21.10 -Properties of nuclei; nuclear energy levels. PACS 21.60 -Nuclear-structure models and methods. PACS 01.30.Cc -Conference proceedings. -IntroductionIn the past decade significant progress has been made in the exploration of hitherto unaccessible regions of the nuclear chart at the limits of stability and by the further development of nuclear models. Key contributions from GSI were the production of the heaviest elements known today [1,2] with Z = 107 to 112, the discovery of the proton radioactivity from the ground state [3] and the first observation of the doubly magic nuclei [4,5] 100 Sn and 78 Ni. A region covering more than hundred new masses was measured with high precision. In nuclear reactions at relativistic energies the enhancement of matter radii towards the driplines and the halo dynamics in light exotic proton-and neutron rich nuclei [6,7] such as 8 B and 11 Li were investigated ( fig. 1). Prerequisites to these studies were new experimental techniques such as separation ion-flight, beams of exotic nuclei at relativistic energies, 4-detector systems of high efficiency, and storage and cooling.A new access to nuclear structure was opened up by isotope separated projectile fragments at intermediate and high energies. After the first pioneering experiments at Berkeley [8,9] this field started growing fast. At present the existing facilities at NSCL (MSU,USA), GSI (Darmstadt, Germany) and ARENAS (Louvain-la-Neuve) -the pioneering laboratory for post-acceleration of secondary beams -are currently upgraded. A

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Production and identification of100Sn

Cited by 137 publications

References 5 publications

Discovery and investigation of heavy neutron-rich isotopes with time-resolved Schottky spectrometry in the element range from thallium to actinium

Discovery and investigation of heavy neutron-rich isotopes with time-resolved Schottky spectrometry in the element range from thallium to actinium

Production of neutron-rich nuclei in fragmentation reactions of Sn132 projectiles at relativistic energies

Perspectives for nuclear structure research at GSI—from halo nuclei to superheavy elements

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