Ejected Electron Slows Molecule’s Rotation

For the conversion from C−2C2− to C2C2 to occur, the final state must have lower energy than the initial state. However, in a rapidly rotating molecule, the energies of the electronic states differ from those in a nonrotating molecule. Schmidt and her colleagues found theoretically that when C−2C2− has 155 or more quanta of angular momentum, a certain excited electronic state has less energy than the C2C2 state to which it would normally convert. The transition is impossible unless the ejected electron removes enough angular momentum to shift the final state’s energy below the initial state’s energy.

The researchers’ theory for such “rotationally assisted” transitions showed that processes requiring a transfer of six units of angular momentum are responsible for the 3-millisecond C−2C2− lifetime the team observed at the MPIK Cryogenic Storage Ring. Schmidt expects similar processes to occur in other highly excited molecules both in the atmosphere and in nuclear-fusion plasmas.

–David Ehrenstein

David Ehrenstein is a Senior Editor for Physics Magazine.
ReferencesV. C. Schmidt et al., “Autodetachment of diatomic carbon anions from long-lived high-rotation quartet states,” Phys. Rev. Lett. 133, 183001 (2024).
V. C. Schmidt et al., “Unimolecular processes in diatomic carbon anions at high rotational excitation,” Phys. Rev. A 110, 042828 (2024).