Dication Explained

A dication is any cation, of general formula X²⁺, formed by the removal of two electrons from a neutral species.

Diatomic dications corresponding to stable neutral species (e.g. formed by removal of two electrons from H₂) often decay quickly into two singly charged particles (H⁺), due to the loss of electrons in bonding molecular orbitals. Energy levels of diatomic dications can be studied with good resolution by measuring the yield of pairs of zero-kinetic-energy electrons from double photoionization of a molecule as a function of the photoionizing wavelength (threshold photoelectrons coincidence spectroscopy – TPEsCO). The dication is kinetically stable.

An example of a stable diatomic dication which is not formed by oxidation of a neutral diatomic molecule is the dimercury dication . An example of a polyatomic dication is, formed by oxidation of S₈ and unstable with respect to further oxidation over time to form SO₂.

Many organic dications can be detected in mass spectrometry for example (a complex) and the acetylene dication .^[1] The adamantyl dication has been synthesized.^[2]

Divalent metals

Some metals are commonly found in the form of dications when in the form of salts, or dissolved in water. Examples include the alkaline earth metals (Be²⁺, Mg²⁺, Ca²⁺, Sr²⁺, Ba²⁺, Ra²⁺); later 3d transition metals (V²⁺, Cr²⁺, Mn²⁺, Fe²⁺, Co²⁺, Ni²⁺, Cu²⁺, Zn²⁺); group 12 elements (Zn²⁺, Cd²⁺, Hg²⁺); and the heavy members of the carbon group (Sn²⁺, Pb²⁺).

Presence in space

Multiply-charged atoms are quite common in the Solar system in the so-called Solar wind. Among these, the most abundant dication is He²⁺. However, molecular dications, in particular CO₂²⁺, have never been observed so far though predicted to be present for instance at Mars.^[3] Indeed, this ion by means of its symmetry and strong double bounds is more stable (longer lifetime) than other dications. In 2020, the molecular dication CO₂²⁺ has been confirmed to be present in the atmosphere of Mars^[4] and around Comet 67P.^[5]

Notes and References

1. Lammertsma . K. . von Ragué Schleyer . P. . Schwarz . H. . 1989 . Organic Dications: Gas Phase Experiments and Theory in Concert . Angew. Chem. Int. Ed. Engl. . 28 . 10 . 1321–1341 . 10.1002/anie.198913211.
2. Bremer . Matthias . von Ragué Schleyer . Paul . Schötz . Karl . Kausch . Michael . Schindler . Michael . Four-Center Two-Electron Bonding in a Tetrahedral Topology. Experimental Realization of Three-Dimensional Homoaromaticity in the 1,3-Dehydro-5,7-adamantanediyl Dication . Angewandte Chemie International Edition in English . August 1987 . 26 . 8 . 761–763 . 10.1002/anie.198707611 . en . 0570-0833.
3. Witasse. O. . Dutuit . O. . Lilensten . J. . Thissen . R. . Zabka . J. . Alcaraz . C. . Blelly . P.-L. . Bougher . S. W. . Engel . S. . Andersen . L.H. . Seiersen . K. . 2020 . Prediction of a CO₂²⁺ layer in the atmosphere of Mars . Geophysical Research Letters . 29 . 8 . 104-1-104-4 . 10.1029/2002GL014781. 129035959 . free .
4. Gu. H. . Cui . J. . Diu . D. . Dai . L. . Huang . J. . Wu . X. . Hao . Y. . Wei . Y. . 2020 . Observation of CO₂²⁺ dication in the dayside Martian upper atmosphere . Earth and Planetary Physics . 4 . 4 . 396–402 . 10.26464/epp2020036. 219929017 . free .
5. Beth. A. . Altwegg . K. . Kathrin Altwegg. Balsiger . H. . Berthelier . J.-J. . Combi . M. R. . De Keyser . J. . Fiethe . B. . Fuselier . S.A. . Galand . M. . Gombosi . T.I. . Rubin . M. . Sémon . T. . 2020 . ROSINA ion zoo at Comet 67P . Astronomy and Astrophysics . 642 . October 2020 . A27 . 10.1051/0004-6361/201936775. 221172890 . free . 2008.08430 .