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A Borromean nucleus is an atomic nucleus comprising three bound components in which any subsystem of two components is unbound. This has the consequence that if one component is removed, the remaining two comprise an unbound resonance, so that the original nucleus is split into three parts.
Many Borromean nuclei are light nuclei near the nuclear drip lines that have a nuclear halo and low nuclear binding energy. For example, the nuclei 6
, and 22
each possess a two-neutron halo surrounding a core containing the remaining nucleons. These are Borromean nuclei because the removal of either neutron from the halo will result in a resonance unbound to one-neutron emission, whereas the dineutron (the particles in the halo) is itself an unbound system. Similarly, 17
is a Borromean nucleus with a two-proton halo; both the diproton and 16
Several Borromean nuclei such as 9
and the Hoyle state (an excited resonance in 12
) play an important role in nuclear astrophysics. Namely, these are three-body systems whose unbound components (formed from 4
) are intermediate steps in the triple-alpha process; this limits the rate of production of heavier elements, for three bodies must react nearly simultaneously.
Borromean nuclei consisting of more than three components can also exist. These also lie along the drip lines; for instance, 8
is a five-body Borromean system with a four-neutron halo. It is also possible that nuclides produced in the alpha process (such as 12
) may be clusters of alpha particles, having a similar structure to Borromean nuclei.
As of 201229
. Heavier species along the neutron drip line have since been observed; these and undiscovered heavier nuclei along the drip line are also likely to be Borromean nuclei with varying numbers (3, 5, 7, or more) of bodies.