Geophysical sensing in the open ocean is both costly and technically challenging. Here we developed a novel distributed fiber optic sensing technique that employs microwave modulation for phase measurement in signals returned from submarine repeaters. We transformed a trans-Atlantic telecom cable into an 81-sensor array and measured sub-millihertz strains. The strains spatiotemporally correlate with ocean tide height variations in phase, suggesting a dominant factor of the cable’s Poisson’s effect. Large strains observed at fiber spans located in the shallow waters match the strong variations of simulated seafloor temperature. This study presents the first experimental confirmation of detecting sub-millihertz signals with trans-oceanic submarine cables at span-wise spatial resolution (~80km). Scaling this technique to operational submarine cables provides a cost-efficient, non-disruptive approach for tsunami early warning and long-term ocean temperature monitoring.