posted on 2020-01-16, 20:48authored byIl-Kwon Oh, Li Zeng, Jae-Eun Kim, Jong-Seo Park, Kangsik Kim, Hyunsoo Lee, Seunggi Seo, Mohammad Rizwan Khan, Sangmo Kim, Chung Wung Park, Junghoon Lee, Bonggeun Shong, Zonghoon Lee, Stacey F. Bent, Hyungjun Kim, Jeong Young Park, Han-Bo-Ram Lee
Fine-tuning
of the surface free energy (SFE) of a solid material
facilitates its use in a wide range of applications requiring precise
control of the ubiquitous presence of liquid on the surface. In this
study, we found that the SFE of rare-earth oxide (REO) thin films
deposited by atomic layer deposition (ALD) gradually decreased with
increasing film thickness; however, these changes could not be understood
by classical interaction models. Herein, the mechanism underlying
the aforesaid decrease was systematically studied by measuring contact
angles, surface potential, adhesion force, crystalline structures,
chemical compositions, and morphologies of the REO films. A growth
mode of the REO films was observed: layer-by-layer growth at the initial
stage with an amorphous phase and subsequent crystalline island growth,
accompanied by a change in the crystalline structure and orientation
that affects the SFE. The portion of the surface crystalline facets
terminated with (222) and (440) planes evolved with an increase in
ALD cycles and film thickness, as an amorphous phase was transformed.
Based on this information, we demonstrated an SFE-tuned liquid tweezer
with selectivity to target liquid droplets. We believe that the results
of this fundamental and practical study, with excellent selectivity
to liquids, will have significant impacts on coating technology.