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The properties of nuclei being investigated include: the excitation energy spectra, the characterization of the static and dynamic moments of inertia, as well as the transition quadrupole moments [derived from lifetime measurements in the range (1-50)x10-15s]. In turn, these experimental results are compared with theoretical models to learn about the strength of the polarizing influence of the deformation driving high L orbitals.
We have concentrated our effort on the medium (A ~ 80-90) and light
mass systems (A ~ 40-50). Since the population of SD structures in these
systems by fusion reactions occurs only 1 to 10 times per 10,000 reactions,
powerful gamma-ray spectroscopic techniques are needed. To this end, the
Gammasphere Array (consisting of ~ 100 large Compton suppressed Ge spectrometers)
is used. However, even the power of Gammasphere is not enough to allow
clear characterization of the properties of these rotational band structures.
We have to resort to further enhancements provided by the "Microball",
our 4p charged-particle multi-detector array,
capable of detecting with high efficiency protons and alpha particles and
of providing their energies. This allows us to select exit channels and
reduce the unwanted background. From the particle momenta we can determine
the recoiling nucleus direction and thus do precise Doppler corrections
on an event-by-event basis. As a result the energy resolution for gamma
rays improves by as much as a factor of 3 depending on exit channel.
However, in order to reach the most neutron deficient nuclei along
the N=Z line and even more neutron deficient systems approaching
the proton drip line (proton binding energy vanishes) one needs to combine
the above techniques with the additional selection provided by the rarely
emitted neutrons. A high efficiency Shell of 30 Neutron Detectors
was designed and constructed for this purpose. It aids tremendously the
study of neutron deficient nuclei which we found to exhibit shape coexistence
between spherical and well deformed structures. We found that some of
these nuclei such as 58,59Cu, and 56Ni are proton
of alpha particle emitters from the lowest states of their deformed structures.
These investigations are continuing.
Independent studies in the light mass systems (A ~ 40-50) will aim to
obtain definitive evidence for superdeformation, alpha clustering in nuclei,
and the role played by the proton-neutron pairing interaction in determining
the high-spin structure of nuclei with N = Z neutron and proton numbers.
We are at present looking for highly deformed structures in the spherical
doubly magic 40Ca nucleus and its neighbor 42Ca.
See also research in the publications listed in the Microball
Home page.
Also you can find here a description of the Neutron
Shell.
As a new direction our group, with the initiative of Dr. W. Reviol,
is moving in the direction of the high spin spectroscopy of heavy and trans lead
nuclei. There, we plan to look for effects on structure of the ultra high L
orbitals like the j15/2 and k17/2 ones.
These are orbitals that drive the nucleus to stable large deformation configurations.
Shape with 3:1 axes ratio are predicted to occur in selected nuclei in
the heavy transuranium elements. In addition, exotic shapes of large oblate
deformations are predicted in the light Pb isotopes (184,186Pb
).
Technically, these species can only be formed in fusion reactions.
Such experiments face the great difficulty that a large majority of the
compound nuclei formed in these fusion experiments lead to fission.
In order to avoid this enormous background of unwanted gamma rays, we
are building a new detector system that is capable of identifying the fusion
products by virtue of their slow velocity (large time of flight). The device
bares the acronym HERCULES (High Efficiency Evaporation Residue Counter
Under a Lot of Elastic Scattering). It consists of 4 rings of 64 very thin
scitillators (< 1 mg/cm2) viewed by fast photomultiplier
tubes. The detectors are not protected from elastic scattering and they
are designed with very fast electronics to be able to operate at counting
rates of 1-2 MHz per detector.
Experiments with HERCULES will begin at LBNL in February 2001.
[Professor Info] [Current Publications] [Research Group]