An international team led by chemists at the University of British Columbia (UBC), Canada, has reported strong experimental evidence for a superfluid phase in molecular hydrogen at 0.4 K. This phase, theoretically predicted in 1972, had only been observed in helium and ultracold atomic gases until now, and never in molecules. The work could give scientists a better understanding of quantum phase transitions and collective phenomena. More speculatively, it could advance the field of hydrogen storage and transportation.
Superfluidity is a quantum mechanical effect that occurs at temperatures near absolute zero. As the temperatures of certain fluids approach this value, they undergo a transition to a zero-viscosity state and begin to flow without resistance – behaviour that is fundamentally different to that of ordinary liquids.
Previously, superfluidity had been observed in helium (3He and 4He) and in clusters of ultracold atoms known as Bose-Einstein condensates. In principle, molecular hydrogen (H2), which is the simplest and lightest of all molecules, should also become superfluid at ultracold temperatures. Like 4He, H2 is a boson, so it is theoretically capable of condensing into a superfluid phase. The problem is that it is only predicted to enter this superfluid state at a temperature between 1 and 2 K, which is lower than its freezing point of 13.8 K.
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