Difference between revisions of "Fabrication and Wetting Properties of Metallic Half-Shells with Sub-Micron Diameters"

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== Experiment ==
 
== Experiment ==
[[Image:Love-contact_angles.jpg|300px|thumb|right|Love, J.C., et al. Nanoletters. 2002 10.1021/nl025633l]]
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[[Image:Love-contact_angles.jpg|300px|thumb|right|Left-hand image: water drop on uncoated gold half-shells.  Right-hand image: Water drop on gold half-shells coated with hexadecanethiolate. Love, J.C., et al. Nanoletters. 2002 10.1021/nl025633l]]
  
 
After fabricating the half-shells, experiments were conducted to determine how much the shell geometry might modify the wetting properties of gold.  For a smooth, unmodified, thin film of gold deposited by physical vapor deposition, the typical contact angle for a drop of water was ~73 degrees.  The contact angle for bare, unmodified gold half-shells fabricated in the same vapor deposition was ~151 degrees.  Love, et al. attribute the increased contact angle to the increased surface roughness caused by the presence of the 290nm diameter, 10nm thick gold half-shells.  These contact angles were measured using a hanging, 5 microliter drop of water.
 
After fabricating the half-shells, experiments were conducted to determine how much the shell geometry might modify the wetting properties of gold.  For a smooth, unmodified, thin film of gold deposited by physical vapor deposition, the typical contact angle for a drop of water was ~73 degrees.  The contact angle for bare, unmodified gold half-shells fabricated in the same vapor deposition was ~151 degrees.  Love, et al. attribute the increased contact angle to the increased surface roughness caused by the presence of the 290nm diameter, 10nm thick gold half-shells.  These contact angles were measured using a hanging, 5 microliter drop of water.
  
 
A surface is considered superhydrophobic if the advancing contact angle of a water drop is greater than 150 degrees.  Love, et al. have shown that simply by changing the surface roughness of chemically identical gold surfaces, the surface can be made to be superhydrophobic.  However, after the hanging drop measurement, the edges of the drop remained pinned and as the drop was withdrawn from the surface, a small part of it remained behind.  This indicates that the entire surface is not superhydrophobic.  By forming a monolayer of hexadecanethiolate on the gold shells, the contact angle measured by hanging drop was increased to ~163 degrees, and no parts of the drop adhered to the surface.  See figure at right for details.
 
A surface is considered superhydrophobic if the advancing contact angle of a water drop is greater than 150 degrees.  Love, et al. have shown that simply by changing the surface roughness of chemically identical gold surfaces, the surface can be made to be superhydrophobic.  However, after the hanging drop measurement, the edges of the drop remained pinned and as the drop was withdrawn from the surface, a small part of it remained behind.  This indicates that the entire surface is not superhydrophobic.  By forming a monolayer of hexadecanethiolate on the gold shells, the contact angle measured by hanging drop was increased to ~163 degrees, and no parts of the drop adhered to the surface.  See figure at right for details.

Revision as of 04:59, 9 February 2009

Short Overview

This paper presents work from Love, et al. concerning fabrication of metallic shells. Thin metallic shells are deposited on and then released from spherical molds. Treated with self-assembled monolayers, aggregates of these shells can be made superhydrophobic. In addition to forming structures that affect the wetting properties of a surface, it is postulated that the thin, metal edges of the half-shells can provide strong enhancements in optical and magnetic fields.

Fabrication of Half-Shells

Love, J.C., et al. Nanoletters. 2002 10.1021/nl025633l

As illustrated in the figure at right, fabrication of the half-shells occurs in four main steps:

- monolayers or multilayer of silica colloids are prepared by drop-casting aqueous suspensions of the particles onto glass slides
- an adhesion layer of titanium or nickel followed by a thin film of gold, platinum, or palladium are deposited onto the colloids via electron-beam evaporation
- spherical colloids are released from the glass slide by sonication
- silica and adhesion metal are dissolved by etching the colloids in hydrofluoric acid (HF), leaving only the thin shell

Experiment

Left-hand image: water drop on uncoated gold half-shells. Right-hand image: Water drop on gold half-shells coated with hexadecanethiolate. Love, J.C., et al. Nanoletters. 2002 10.1021/nl025633l

After fabricating the half-shells, experiments were conducted to determine how much the shell geometry might modify the wetting properties of gold. For a smooth, unmodified, thin film of gold deposited by physical vapor deposition, the typical contact angle for a drop of water was ~73 degrees. The contact angle for bare, unmodified gold half-shells fabricated in the same vapor deposition was ~151 degrees. Love, et al. attribute the increased contact angle to the increased surface roughness caused by the presence of the 290nm diameter, 10nm thick gold half-shells. These contact angles were measured using a hanging, 5 microliter drop of water.

A surface is considered superhydrophobic if the advancing contact angle of a water drop is greater than 150 degrees. Love, et al. have shown that simply by changing the surface roughness of chemically identical gold surfaces, the surface can be made to be superhydrophobic. However, after the hanging drop measurement, the edges of the drop remained pinned and as the drop was withdrawn from the surface, a small part of it remained behind. This indicates that the entire surface is not superhydrophobic. By forming a monolayer of hexadecanethiolate on the gold shells, the contact angle measured by hanging drop was increased to ~163 degrees, and no parts of the drop adhered to the surface. See figure at right for details.