https://www-user.pas.rochester.edu/~gosia/mediawiki/index.php?action=history&feed=atom&title=Model_dependent_analysisModel dependent analysis - Revision history2026-06-25T03:06:25ZRevision history for this page on the wikiMediaWiki 1.16.0https://www-user.pas.rochester.edu/~gosia/mediawiki/index.php?title=Model_dependent_analysis&diff=305&oldid=prevHayes: creation2011-04-29T14:53:17Z<p>creation</p>
<p><b>New page</b></p><div>The much improved sensitivity provided by modern<br />
<math>4\pi</math> high-resolution<br />
<math>\gamma</math>-ray<br />
detector facilities, such as Gammasphere when coupled to<br />
<math>4\pi</math> recoil-ion detectors like [[CHICO | CHICO]], has greatly expanded the number of collective<br />
bands and levels observed in heavy-ion induced Coulomb excitation<br />
measurements. Since the late<br />
1990s this improved sensitivity has led to an explosive increase in the number of<br />
<math>E\lambda</math><br />
matrix elements involved in least-squares fits to Coulomb excitation data. For<br />
example, current heavy-ion induced Coulomb excitation measurements can<br />
populate <math>\approx 100</math> levels in <math>\approx 10</math><br />
collective bands coupled by <math>\approx 3000</math> <math>E\lambda</math><br />
matrix elements. This rapid increase in the number of unknowns, and<br />
concomitant increase in the dimension of the least-squares search problem,<br />
coupled with a reduction in available beam time due to closure of a<br />
substantial fraction of the arsenal of heavy-ion accelerator facilities, has<br />
made it no longer viable to obtain sufficiently complete sets of Coulomb<br />
excitation data for a full model-independent Gosia analysis. Fortunately the<br />
collective correlations are strong for low-lying spectra of most nuclei making<br />
it viable to exploit these collective correlations to greatly reduce the<br />
number of fitted parameters to accommodate the smaller data sets. For example,<br />
for the axially-symmetric rigid rotor the fit to the diagonal and transition<br />
E2 matrix elements can be reduced to fitting the one intrinsic quadrupole moment<br />
of the band, which, in principle, only requires measurement of one<br />
E2 matrix element. Model-dependent analyses of Coulomb excitation data can be<br />
used to extract the relevant physics even when the data set is insufficient to<br />
overdetermine the many unknown matrix elements model independently.<br />
<br />
A model-dependent approach that has been highly successfully involves<br />
factoring the system into subgroups of levels that have similar collective<br />
correlations, and assuming that a model can adequately relate the<br />
<math>E\lambda</math> matrix elements for each of these localized subgroups of levels. That is, the<br />
model is used to relate the <math>E\lambda</math> matrix elements in a localized region by coupling all of the "dependents" to<br />
one "master" member of the subgroup. The least-squares fit then is made to<br />
find the best values of the master matrix elements with the dependents varying<br />
in proportion to the masters. This approach can reduce the number of<br />
parameters being fit by an order of magnitude. The best-fit values for these<br />
master matrix elements then can be used iteratively to refine the<br />
model-dependent coupling employed for correlating the matrix elements in the<br />
localized subgroups. As an example, in strongly-deformed nuclei the ground<br />
rotational band levels below the first band crossing can be broken into one or<br />
two subgroups each of which are coupled to common intrinsic<br />
E2 moments, the levels above the band crossing also can be broken into similar<br />
subgroups, while the individual matrix elements around the band crossing can<br />
be treated as independent parameters. An iterative procedure then can be<br />
employed where models are assumed to be sufficient accurate locally to<br />
extrapolate the measured sensitive matrix elements to model-dependently<br />
predict the less sensitive matrix elements.<br />
<br />
The model-dependent approach must be treated with considerable care because<br />
the strong cross correlations can lead to erroneous conclusions. The fact that<br />
one model fits the experimental Coulomb excitation data is not a proof that<br />
this solution is unique. For example, the Davydov-Chaban rigid-triaxial rotor<br />
model reproduced well the measured Coulomb excitation yields for an early<br />
multiple Coulomb excitation studies of<br />
<math>^{192,194,196}</math>Pt<ref>I.Y. Lee, D. Cline, P.A. Butler, R.M. Diamond, J.O. Newton, R.S. Simon and F.S. Stephens, Phys. Rev. Lett. 39:684 (1977).</ref> implying the existence of rigid triaxial<br />
deformation. A subsequent more extensive Coulomb excitation<br />
study,<ref>C.Y. Wu, Ph.D. Thesis, University of Rochester (1983)</ref>,<ref>C.Y. Wu, D. Cline, T. Czosnyka, et al., Nucl. Phys. A 607:178 (1996).</ref> that was analysed using Gosia,<br />
determined that these nuclei are very soft to<br />
<math>\beta</math>- and<br />
<math>\gamma</math>-vibrational degrees of freedom. The earlier erroneous conclusion that this<br />
nucleus behaved like a rigid triaxial rotor was fortuitous because the early<br />
measurements were sensitive only to the centroids of the<br />
<math>\beta</math> and<br />
<math>\gamma</math> shape degrees of freedom. Another example is that the axially-symmetric model<br />
often can give an almost equally acceptable fits to Coulomb excitation data of<br />
triaxially-deformed nuclei where erroneous<br />
<math>B(E2)</math><br />
strengths compensate for incorrectly assumed static electric quadrupole<br />
moments. Thus it is important to compare the quality of model-dependent fits<br />
using various competing collective models to derive reliable conclusions as to<br />
the relative efficacy of different collective models.<br />
<br />
==Notes==<br />
<br />
<references/></div>Hayes