Condensation
on lubricant-infused micro- or nanotextured superhydrophobic
surfaces exhibits remarkable heat transfer performance owing to the
high condensation nucleation density and efficient condensate droplet
removal. When a low surface tension lubricant is used, it can spread
on the condensed droplet and “cloak” it. Here, we describe
a previously unobserved condensation phenomenon of satellite droplet
formation on lubricant-cloaked water droplets using environmental
scanning electron microscopy. The presence of satellite droplets confirms
the cloaking behavior of common lubricants on water such as Krytox
oils. More interestingly, we have observed satellite droplets on BMIm
ionic liquid-infused surfaces, which is unexpected because BMIm was
used in previous reports as a lubricant to eliminate cloaking during
water condensation. Our studies reveal that the cloaking of BMIm on
water droplets is theoretically favorable due to the fast timescale
spreading during initial condensation when compared to the long timescale
required for dissolution of the lubricant in water. We utilize a novel
characterization approach based on Raman spectroscopy to confirm the
existence of cloaking lubricant films on water droplets residing on
lubricant-infused surfaces. The selected lubricants include Krytox
oil, ionic liquid, and dodecane, which have drastically different
surface tensions and polarities. In addition, spreading dynamics of
cloaking and noncloaking lubricants on water droplets show that ionic
liquid has the capability to mobilize water droplets spontaneously
owing to cloaking and its relatively high surface tension. Our studies
not only elucidate the physics governing cloaking and satellite droplet
condensation phenomena at micro- and macroscales but also reveal a
subset of previously unobserved lubricant–water interfacial
interactions for a large variety of applications.