AbstractSpontaneous droplet jumping on microâ/nanoâstructured superhydrophobic surfaces has been exploited as an efficient means for enhancing steam condensation heat transfer. However, the good performance of such surfaces quickly decays with raising the degree of subcooling, due to the mismatch between the characteristic length scales and droplet sizes when they grow up. Herein, a novel strategy for multiscale droplet regulation is proposed by combining subâmillimeter fin structure with a hierarchical microporous superhydrophobic surface. A superior condensation heat transfer performance is attained on such hierarchical superhydrophobic finned tube (FâSHB), in comparison to the baseline case of superhydrophobic nonâfinned (SHB) tube under wellâcontrolled test conditions. Although the droplet jumping is not as vigorous as that on the SHB tube, the finned geometry of the FâSHB tube leads to a condensation heat transfer enhancement even under high degrees of subcooling up to 36 K, because of the accelerated departure of large droplets by imposing Laplace force gradient in the presence of Vâshaped subâmillimeter fins. This multiscale enhancement strategy is shown to enable a cascading regulation over the entire lifespan of condensate droplets. The fabrication of FâSHB tubes is facile and easy to be scaled up, showing great potential in practical steam condensation applications.