Some, like Russian dolls, fit inside each other
By Neal Singer
Back to Lab News Table of Contents
The achievement, which has medical, industrial, and military potential, is featured in the March 18 issue of the journal Nature. .
THEY CAME FROM INNER SPACE -- Sandia researcher Jeff Brinker (1831) observes the structures of a variety of submicroscopic spheres created by his team at the nanometer scale. (Photo by Randy Montoya)
Download 150dpi JPEG image, 'brinker_pix.jpg', 1.5 Mb
The durable silica spheres, which range in size from 2 to 50 nanometers, form in a few seconds, are small enough to be introduced into the body, and have uniform pores that could enable controlled release of drugs.
The spheres can absorb organic and inorganic substances including small particles of iron, which means they can be controlled by magnets and the contents released as needed.
The small porous particles also have characteristics superior to fillers used in encapsulants for weapons and tools. The expansion coefficients of polymers and the metallic devices they cradle usually differ substantially.
This means that temperature variations cause the encapsulants to stress the devices they are meant to protect. The induced stresses can decrease longevity of a device. Nanosphere fillers would occupy the same volume, but because they are porous can expand and contract with much less stress.
The Sandia nanospheres also may be useful as coatings on silicon chips whose increasingly tiny circuits require a medium that has a lower dielectric constant and stores less heat.
Pore shapes trap materials
Some pore shapes trap materials, while others allow free flow in and out of the spheres.
The different kinds of sphere porosity may resemble slits between onion-like layers of silica, or a honeycomb's hexagonal patterns of holes, or the cubic gaps in a network of connected tinkertoys.
"The ability to control these different porosities makes them useful for all kinds of applications," says Sandia lead investigator Jeff Brinker (1831).
"If they were simply porous particles, they would not be nearly so interesting."
Silicon and surfactant
The mixture begins with a homogeneous solution of soluble silica plus surfactant prepared in an ethanol water solvent. In a continuous process that takes about six seconds per particle, the aerosol particles are dried, heated, and collected.
"We start out with liquid droplets that we pass through a reactor," says Jeff.
"As liquid starts to evaporate, the rest of the material self-assembles into a completely ordered particle that, when heated, maintains its shape."
The spheres are the most intriguing in a series of advances by Jeff and his research associates, all reported in previous issues of Nature.
Prior results by Jeff's team used simpler but similar techniques to self-assemble highly porous thin films to overlay and greatly increase the porosity and therefore sensitivity of handheld detectors.
Following that achievement came self-assembled laminates that resemble seashells in appearance and properties. This method of self-assembly improved the strength of human-created materials by sandwiching yielding layers of polymers between hard inorganic layers, increasing toughness and preventing the spreading of cracks.
The nano-spheres -- essentially a three-dimensional creation rather than a film or layering of films -- were created by drying liquid droplets blowing through a furnace, rather than evaporating a liquid layer deposited on a substrate.
The work was supported by DOE's Basic Energy Science Program and the University of New Mexico (UNM)/ National Science Foundation Center for Micro-Engineered Materials.
Other authors -- all at UNM's Advanced Materials Laboratory -- are Yunfeng Lu, Hongyou Fan, Aaron Stump, Tim Ward, and Thomas Rieker.
Last modified: April 2, 1999
View Sandia news releases and fact sheets
Questions and Comments || Acknowledgment and Disclaimer