posted on 2017-04-06, 00:00authored byWenjia Song, Yan Lavallée, Fabian B. Wadsworth, Kai-Uwe Hess, Donald B. Dingwell
A major hazard to jet engines posed
by volcanic ash is linked to
the wetting and spreading of molten ash droplets on engine component
surfaces. Here, using the sessile drop method, we study the evolution
of the wettability and spreading of volcanic ash. We employ rapid
temperature changes up to 1040–1450 °C, to replicate the
heating conditions experienced by volcanic ash entering an operating
jet engine. In this scenario, samples densify as particles coalesce
under surface tension until they form a large system-sized droplet
(containing remnant gas bubbles and crystals), which subsequently
spreads on the surface. The data exhibit a transition from a heterogeneous
to a homogeneous wetting regime above 1315 °C as crystals in
the drops are dissolved in the melt. We infer that both viscosity
and microstructural evolution are key controls on the attainment of
equilibrium in the wetting of molten volcanic ash droplets.