The Molecular Gas-Star Formation Connection in an Optically-Selected Sample of Interacting Galaxies

We have obtained CO(1-0) observations for a sample of 37 interacting galaxy systems, chosen from a parent sample of optically-selected interacting galaxies. The sample observed here spans a large range of interaction strengths and star formation rates (SFR). Using the standard CO-to-H2 conversion factor we find that the interacting galaxies are, on average, marginally more rich in molecular gas than a comparison sample of isolated spiral galaxies, having mean H2/LB and H2/HI ratios 20-40% higher than isolated spirals. The interacting galaxies also have a mean LIR/MH2 ratio that is a factor of ~1.3 higher than the isolated galaxies. There is a strong correlation between relative H2 content and SFRs, indicating that the level of interaction-induced star formation activity is very dependent upon the the available gas supply. Some galaxies, however, have moderate amounts of H2 but much lower than normal SFRs. Therefore molecular gas is a necessary, but not sufficient, prerequisite for star formation. There is also a strong correlation between interaction strength and both SFR and relative H2 content. If the increase in H2 content is real, there must be a substantial conversion of HI to H2 gas taking place in the strongest interacting systems. At least some portion of this apparent increase, however, could be due to non-standard CO-to-H2 conversion factors. A reduction in the conversion factor by amounts consistent with that applicable to ultraluminous infrared galaxies would completely account for the systematic increase in derived H2 content as a function of interaction strength. Such a change could not, however, account for the total range of relative H2 content as a function of SFR. Therefore the correlation between molecular gas content and star formation rate must be real.