Litcius/Paper detail

Coalescence‐Induced Jumping Bubbles during Pool Boiling

Hyunggon Park, S. Farzad Ahmadi, Thomas Foulkes, Jonathan B. Boreyko

2023Advanced Functional Materials29 citationsDOI

Abstract

Abstract Surfaces with micro/nano‐structures significantly enhance the critical heat flux of nucleate boiling by increasing the wickability of the liquid phase to delay film boiling. An alternative strategy, of removing surface bubbles at smaller sizes, is largely ignored. Here, they fabricate a rationally designed micro‐structured surface that enables the coalescence‐induced departure of microscopic vapor bubbles during the pool boiling of water at diameters an order of magnitude smaller than single‐bubble buoyant departure. Arrays of micro‐cavities or micro‐grooves serve as tailored nucleation sites to nucleate close‐packed vapor bubbles, which coalesce at unusually small sizes compared to a homogeneous surface. Two different modes of coalescence‐induced bubble departure are observed and modeled: capillary‐inertial jumping for smaller micro‐bubbles and buoyant‐inertial liftoff for larger micro‐bubbles. Capillarity‐enhanced pool boiling on micro‐structured surfaces has the potential to dramatically enhance the heat transfer coefficient and critical heat flux of pool boiling.

Topics & Concepts

Materials scienceBoilingCoalescence (physics)BubbleNucleate boilingNucleationMechanicsHeat fluxCritical heat fluxCapillary actionThermodynamicsHeat transferComposite materialPhysicsAstrobiologyHeat Transfer and Boiling StudiesFluid Dynamics and Heat TransferFluid Dynamics and Thin Films