0000000000105295

AUTHOR

Rolf-dietmar Herzberg

showing 9 related works from this author

A Geant4 simulation package for the sage spectrometer

2012

International audience; A comprehensive Geant4 simulation was built for the SAGE spectrometer. The simulation package includes the silicon and germanium detectors, the mechanical structure and the electromagnetic fields present in SAGE. This simulation can be used for making predictions through simulating experiments and for comparing simulated and experimental data to better understand the underlying physics.

Electromagnetic fieldHistorySiliconSpectrometer010308 nuclear & particles physicsComputer sciencePhysics::Instrumentation and DetectorsDetectorchemistry.chemical_elementExperimental dataGermaniumComputerApplications_COMPUTERSINOTHERSYSTEMS[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]01 natural sciencesComputer Science ApplicationsEducationComputational scienceKokeellinen ydinfysiikkachemistry0103 physical sciencesComputer Science::Mathematical Software29.40.Wk Solid-state detectors 29.30.Kv X- and gamma-ray spectroscopy 07.85.Nc X-ray and gamma-ray spectrometers 29.30.Dn Electron spectroscopyExperimental nuclear physics010306 general physics
researchProduct

The SAGE spectrometer: A tool for combined in-beam gamma-ray and conversion electron spectroscopy

2010

International audience; The sage spectrometer allows simultaneous in-beam -ray and internal conversion electron measurements, by combining a germanium detector array with a highly segmented silicon detector and an electron transport system. sage is coupled with the ritu gas- lled recoil separator and the great focal-plane spectrometer for recoil-decay tagging studies. Digital electronics are used both for the ray and the electron parts of the spectrometer. sage was commissioned in the Accelerator Laboratory of the University of Jyvaskyla in the beginning of 2010.

PhysicsHistorySpectrometer010308 nuclear & particles physicsbusiness.industryPhysics::Instrumentation and DetectorsElectron[PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex]7. Clean energy01 natural sciencesElectron spectroscopyRecoil separatorComputer Science ApplicationsEducationSemiconductor detectorNuclear physicsOpticsInternal conversion0103 physical sciencesSilicon detectorHigh Energy Physics::Experiment010306 general physicsbusinessNuclear ExperimentBeam (structure)
researchProduct

Superheavy element flerovium (element 114) is a volatile metal.

2014

The electron shell structure of superheavy elements, i.e., elements with atomic number Z ≥ 104, is influenced by strong relativistic effects caused by the high Z. Early atomic calculations on element 112 (copernicium, Cn) and element 114 (flerovium, Fl) having closed and quasi-closed electron shell configurations of 6d(10)7s(2) and 6d(10)7s(2)7p1/2(2), respectively, predicted them to be noble-gas-like due to very strong relativistic effects on the 7s and 7p1/2 valence orbitals. Recent fully relativistic calculations studying Cn and Fl in different environments suggest them to be less reactive compared to their lighter homologues in the groups, but still exhibiting a metallic character. Expe…

Physicsgas chemistryValence (chemistry)ta114Electron shellchemistry.chemical_elementelement 114Inorganic ChemistryFleroviumsuperheavy elementsPhysisorptionchemistryAtomic orbitalChemical physicsSubatomic PhysicsAtomic numberPhysical and Theoretical ChemistryAtomic physicsRelativistic quantum chemistryCoperniciumInorganic chemistry
researchProduct

The SPEDE Spectrometer: Combined In-Beam γ-ray and Conversion Electron Spectroscopy with Radioactive Ion Beams

2015

The SPEDE spectrometer [1] aims to combine a silicon detector, for the detection of electrons, with the MINIBALL γ-ray detection array for in-beam studies employing radioactive ion beams at the HIE-ISOLDE facility at CERN. The setup will be primarily used for octupole collectivity [2] and shape coexistence studies [3, 4] in Coulomb excitation experiments. In the shape coexistence cases the transitions between states of the same spin and parity have enhanced E0 strength [5]. Additionally the 0→0 transitions, typically present in nuclei exhibiting shape coexistence [6], can only occur via E0 transitions, i.e. via internal conversion electron emission.

Radioactive ion beamsPhysicsLarge Hadron ColliderSpectrometerta114Physics::Instrumentation and DetectorsParity (physics)Coulomb excitationElectronElectron spectroscopyPhysics::Accelerator PhysicsSilicon detectorAtomic physicsconversion electron spectrometersNuclear Experiment
researchProduct

Lessons learned with the SAGE spectrometer

2012

The SAGE spectrometer combines a high-efficiency γ-ray detection system with an electron spectrometer. Some of the design features have been known to be problematic and surprises have come up during the early implementation of the spectrometer. Tests related to bismuth germanate Compton-suppression shields, electron detection efficiency and an improved cooling system are discussed in the paper.

Electron spectrometerMaterials scienceSpectrometerPhysics::Instrumentation and Detectors010308 nuclear & particles physicsbusiness.industryShieldsElectronCondensed Matter Physics01 natural sciencesBismuth germanateAtomic and Molecular Physics and Opticschemistry.chemical_compoundOpticschemistry0103 physical sciencesWater coolingNuclear Experiment010306 general physicsbusinessMathematical PhysicsRemote sensingPhysica Scripta
researchProduct

Transmission Efficiency of the SAGE Spectrometer Using GEANT4

2013

The new SAGE spectrometer allows simultaneous electron and γ-ray in-beam studies of heavy nuclei. A comprehensive GEANT4 simulation suite has been created for the SAGE spectrometer. This includes both the silicon detectors for electron detection and the germanium detectors for γ-ray detection. The simulation can be used for a wide variety of tests with the aim of better understanding the behaviour of SAGE. A number of aspects of electron transmission are presented here.

Materials scienceSpectrometerSiliconta114Physics::Instrumentation and Detectors010308 nuclear & particles physicsbusiness.industrySAGEDetectorchemistry.chemical_elementGermaniumElectron01 natural sciences3. Good healthElectron transmissionchemistryTransmission (telecommunications)0103 physical sciencesOptoelectronicsComputer Science::Symbolic ComputationNuclear Experiment010306 general physicsbusinessFission and Properties of Neutron-Rich Nuclei, pg. 332 (2013)
researchProduct

Chemical studies of Fl (element 114): Heaviest chemically studied element

2017

researchProduct

First prompt in-beam gamma-ray spectroscopy of a superheavy element: the 256Rf

2013

Using state-of-the-art γ-ray spectroscopic techniques, the first rotational band of a superheavy element, extending up to a spin of 20 ¯h, was discovered in the nucleus 256Rf. To perform such an experiment at the limits of the present instrumentation, several developments were needed. The most important of these developments was of an intense isotopically enriched 50Ti beam using the MIVOC method. The experimental set-up and subsequent analysis allowed the 256Rf ground-state band to be revealed. The rotational properties of the band are discussed and compared with neighboring transfermium nuclei through the study of their moments of inertia. These data suggest that there is no evidence of a…

Experimental Nuclear Physics
researchProduct

Transition probability studies in 175Au

2013

Transition probabilities have been measured between the low-lying yrast states in 175Au by employing the recoil distance Doppler-shift method combined with the selective recoil-decay tagging technique. Reduced transition probabilities and magnitudes of transition quadrupole moments have been extracted from measured lifetimes allowing dramatic changes in nuclear structure within a low excitation-energy range to probed. The transition quadrupole moment data are discussed in terms of available systematics as a function of atomic number and aligned angular momentum. peerReviewed

Physics::Atomic PhysicsExperimental Nuclear Physics
researchProduct