posted on 2023-02-20, 12:34authored byCarlos
D. Díaz-Marín, Diane Li, Fernando J. Vázquez-Cosme, Simo Pajovic, Hyeongyun Cha, Youngsup Song, Cameron Kilpatrick, Geoffrey Vaartstra, Chad T. Wilson, Svetlana Boriskina, Evelyn N. Wang
Colloidal self-assembly has attracted significant interest
in numerous
applications including optics, electrochemistry, thermofluidics, and
biomolecule templating. To meet the requirements of these applications,
numerous fabrication methods have been developed. However, these are
limited to narrow ranges of feature sizes, are incompatible with many
substrates, and/or have low scalability, significantly limiting the
use of colloidal self-assembly. In this work, we study the capillary
transfer of colloidal crystals and demonstrate that this approach
overcomes these limitations. Enabled by capillary transfer, we fabricate
2D colloidal crystals with nano-to-micro feature sizes spanning 2
orders of magnitude and on typically challenging substrates including
those that are hydrophobic, rough, curved, or structured with microchannels.
We developed and systemically validated a capillary peeling model,
elucidating the underlying transfer physics. Due to its high versatility,
good quality, and simplicity, this approach can expand the possibilities
of colloidal self-assembly and enhance the performance of applications
using colloidal crystals.