Dirubidium is a molecular substance containing two atoms of rubidium found in rubidium vapour. Dirubidium has two active valence electrons. It is studied both in theory and with experiment. The rubidium trimer has also been observed.
Dirubidium is produced when rubidium vapour is chilled. The enthalpy of formation (ÃÂ<sub>f</sub>H<sup>ð</sup>) in the gas phase is 113.29 kJ/mol. In practice, an oven heated to 600 to 800K with a nozzle can squirt out vapour that condenses into dimers. The proportion of Rb<sub>2</sub> in rubidium vapour varies with its density, which depends on the temperature. At 200ð the partial pressure of Rb<sub>2</sub> is only 0.4%, at 400 ðC it constitutes 1.6% of the pressure, and at 677 ðC the dimer has 7.4% of the vapour pressure (13.8% by mass).
The rubidium dimer has been formed on the surface of helium nanodroplets when two rubidium atoms combine to yield the dimer:
Rb<sub>2</sub> has also been produced in solid helium matrix under pressure.
Ultracold rubidium atoms can be stored in a magneto-optic trap and then photoassociated to form molecules in an excited state, vibrating at a rate so high they barely hang together. In solid matrix traps, Rb<sub>2</sub> can combine with the host atoms when excited to form exciplexes, for example Rb<sub>2</sub>(<sup>3</sup>ÃÂ <sub>u</sub>)He<sub>2</sub> in a solid helium matrix.
Ultracold rubidium dimers are being produced in order to observe quantum effects on well-defined molecules. It is possible to produce a set of molecules all rotating on the same axis with the lowest vibrational level.
Dirubidium has several excited states, and spectral bands occur for transitions between these levels, combined with vibration. It can be studied by its absorption lines, or by laser induced-fluorescence. Laser induced-fluorescence can reveal the life-times of excited states.
In the absorption spectrum of rubidium vapour, Rb<sub>2</sub> has a major effect. Single atoms of rubidium in the vapour cause lines in the spectrum, but the dimer causes wider bands to appear. The most severe absorption between 640 and 730 nm makes the vapour almost opaque from 670 to 700 nm, wiping out the far red end of the spectrum. This is the band due to XâÂÂB transition. From 430 to 460 nm there is a shark-fin shaped absorption feature due to XâÂÂE transitions. Another shark fin like effect around 475 nm s due to XâÂÂD transitions. There is also a small hump with peaks at 601, 603 and 605.5 nm 1âÂÂ3 triplet transitions and connected to the diffuse series. There are a few more small absorption features in the near infrared.
There is also a dirubidium cation, Rb<sub>2</sub><sup>+</sup> with different spectroscopic properties.
The following table has parameters for <sup>85</sup>Rb<sup>85</sup>Rb the most common for the natural element.
The other alkali metals also form dimers: dilithium Li<sub>2</sub>, Na<sub>2</sub>, K<sub>2</sub>, and Cs<sub>2</sub>. The rubidium trimer has also been observed on the surface of helium nanodroplets. The trimer, Rb<sub>3</sub> has the shape of an equilateral triangle, bond length of 5.52 Aàand a binding energy of 929 cm<sup>âÂÂ1</sup>.