Title :
Super wetting of micro &nano structured titania surfaces
Author :
Ding, C. ; Bogorzi, P. ; Srivastava, N. ; Sigurdson, M. ; Meinhart, C. ; MacDonald, N.C.
Author_Institution :
California Nanosystems Inst., Santa Barbara, CA, USA
Abstract :
Surfaces with tunable wettability are of great importance for both fundamental research and practical applications such as heat pipes. In this work, micro-& nano-textured (bitextured) titania structures (BTS) based on titanium micromachining and surface oxidization techniques are proposed to function as wicking material requiring super wetting by common fluids such as water. We show theoretical studies and experimental work to investigate the wetting behavior of two different designs of BTS. For heat pipe applications the BTS not only increases the capillary pressure which enhances liquid pumping, but also increases the heat transfer performance by extended surface and smaller pore sizes.
Keywords :
heat pipes; heat transfer; micromachining; nanostructured materials; nanotechnology; oxidation; titanium compounds; wetting; TiO2; bitextured titania structures; capillary pressure; extended surface; heat pipe applications; heat transfer performance; liquid pumping; microstructured titania surface; nanostructured titania surface; pore size; super wetting; surface oxidization; titanium micromachining; tunable wettability; wicking material; Equations; Heat pumps; Heat sinks; Liquids; Microstructure; Nanostructured materials; Rough surfaces; Solids; Surface roughness; Surface topography; Heat pipe; NST; adiabatic; condenser; evaporator; nanostructure; pillar; titanium; wetting; wick;
Conference_Titel :
Solid-State Sensors, Actuators and Microsystems Conference, 2009. TRANSDUCERS 2009. International
Conference_Location :
Denver, CO
Print_ISBN :
978-1-4244-4190-7
Electronic_ISBN :
978-1-4244-4193-8
DOI :
10.1109/SENSOR.2009.5285479
