Abstract
Abstract
The quantum tunneling and emission of a single constituent nucleon provide a beautifully simple and unique window into the complex properties of atomic nuclei at the extreme edge of nuclear existence. In particular, for odd-odd proton emitting nuclides, the associated decay energy and partial half-life can be used to probe the correlations between the valence neutrons and protons which have been theoretically predicted to favour a new type of nuclear superfluidity, isoscalar neutron-proton pairing, for which the experimental “smoking gun" remains elusive. In the present work, proton emission from the lanthanum isotope
$_{\,57}^{116}$$
57
116
La
59
, 23 neutrons away from the only stable isotope
$_{\,57}^{139}$$
57
139
La
82
, is reported.
116
La nuclei were synthesised in the fusion-evaporation reaction
58
Ni(
64
Zn,
p
5
n
)
116
La and identified via their proton radioactivity using the mass spectrometer MARA (Mass Analysing Recoil Apparatus) and the silicon detectors placed at its focal plane. Comparisons of the measured proton energy (
E
p
= 718 ± 9 keV) and half-life (
T
1/2
= 50 ± 22 ms) with values calculated using the Universal Decay Law approach indicate that the proton is emitted with an orbital angular momentum
l
= 2 and that its emission probability is enhanced relative to its closest, less exotic, odd-even lanthanum isotope (
$_{\,57}^{117}$$
57
117
La
60
) while the proton-emission
Q
-value is lower. We propose this to be a possible signature for the presence of strong neutron-proton pair correlations in this exotic, neutron deficient system. The observations of
γ
decays from isomeric states in
116
La and
117
La are also reported.