Cold Molecule Spectroscopy for Constraining the Evolution of the Fine Structure Constant
arXiv:physics/0601054 · doi:10.1103/PhysRevLett.96.143004
Abstract
We report precise measurements of ground-state, $λ$-doublet microwave transitions in the hydroxyl radical molecule (OH). Utilizing slow, cold molecules produced by a Stark decelerator we have improved over the precision of the previous best measurement by twenty-five-fold for the F' = 2 $\to$ F = 2 transition, yielding (1 667 358 996 $\pm$ 4) Hz, and by ten-fold for the F' = 1 $\to$ F = 1 transition, yielding (1 665 401 803 $\pm$ 12) Hz. Comparing these laboratory frequencies to those from OH megamasers in interstellar space will allow a sensitivity of 1 ppm for $Îα/α$ over $\sim$$10^{10}$ years.
This version corrects minor typos in the Zeeman shift discussion