Dielectronic recombination resonances of Pb (79+) associated with 2s(1/2)-->2p(1/2) excitations were measured at the heavy-ion storage ring ESR at GSI. The fine structure of the energetically lowest resonance manifold Pb (78+)(1s(2)2p(1/2)20l(j)) at around 18 eV could partially be resolved, and rate coefficients on an absolute scale were obtained. A comparison of the experimental data with results of a fully relativistic theoretical approach shows that high-angular-momentum components up to j=31/2 significantly contribute to the total resonance strength demonstrating the necessity to revise the widespread notion of negligible high-angular-momentum contributions at least for very highly charged ions.
The resonance strength of the two-step process of nuclear excitation by
electron capture followed by $\gamma$ decay of the nucleus can be significantly
increased in highly charged ions if the resonant capture proceeds via an
excited electronic state with subsequent fast x-ray emission. For fully ionized
$^{238}_{92}\mathrm{U}$ and $^{232}_{90}\mathrm{Th}$, the {x-ray} decay
stabilizes the system against internal conversion of the captured electron,
with an increase of both nuclear lifetimes and resonance strengths of up to two
orders of magnitude compared with the case when occupied atomic orbitals
prevent the x-ray de-excitation. Applications of this effect to the measurement
of the not yet experimentally observed nuclear excitation by electron capture
and to dense astrophysical plasmas are discussed.Comment: 12 pages, 1 figure, 2 table
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