Stamp turns ‘sponges’ into nanodevices

VANDERBILT (US) — A new stamping technique allows researchers to make a variety of devices from a stiff, sponge-like material filled with incredibly small holes.

For years scientists have been investigating the use of these materials—called porous nanomaterials—for a wide range of applications, including drug delivery, chemical and biological sensors, solar cells, and battery electrodes. The materials are riddled with tiny voids that give them unique optical, electrical, chemical, and mechanical properties.

There are nanoporous forms of gold, silicon, alumina, and titanium oxide, among others.

A major obstacle to using the materials has been the complexity and expense of the processing required to turn them into devices. A new rapid, low-cost imprinting process can stamp out a variety of nanodevices from these intriguing materials.

“It’s amazing how easy it is. We made our first imprint using a regular tabletop vise,” says Sharon Weiss, associate professor of electrical engineering at Vanderbilt University. “And the resolution is surprisingly good.”

Weiss and colleagues report their results in the journal Nano Letters.

Simple stamp
The traditional strategies used for making devices out of nanoporous materials are based on the process used to make computer chips. This must be done in a special clean room and involves painting the surface with a special material called a resist, exposing it to ultraviolet light or scanning the surface with an electron beam to create the desired pattern.

They then apply a series of chemical treatments to either engrave the surface or lay down new material. The more complicated the pattern, the longer it takes to make.

About two years ago, Weiss got the idea of creating pre-mastered stamps using the complex process and then using the stamps to create the devices. Weiss calls the new approach direct imprinting of porous substrates (DIPS). DIPS can create a device in less than a minute, regardless of its complexity. So far, her group reports that it has used master stamps more than 20 times without any signs of deterioration.

Biosensors and more
The smallest pattern that Weiss and her colleagues have made to date has features of only a few tens of nanometers, which is about the size of a single fatty acid molecule. They have also succeeded in imprinting the smallest pattern yet reported in nanoporous gold, one with 70-nanometer features.

The first device the group made is a “diffraction-based” biosensor that can be configured to identify a variety of different organic molecules, including DNA, proteins and viruses. The device consists of a grating made from porous silicon treated so that a target molecule will stick to it.

The sensor is exposed to a liquid that may contain the target molecule and then is rinsed off. If the target was present, then some of the molecules stick in the grating and alter the pattern of reflected light produced when the grating is illuminated with a laser.

Graduate student Judson Ryckman demonstrates the function of a biosensor made using a new technique that imprints patterns on porous nanomaterials. (Credit: Anne Raynor, Vanderbilt University)

According to the researchers’ analysis, when such a biosensor is made from nanoporous silicon it is more sensitive than those made from ordinary silicon.

Researchers used the technique to make nano-patterned chemical sensors that are ten times more sensitive than another type of commercial chemical sensor called Klarite that is the basis of a multimillion-dollar market.

They also demonstrated that they can use the stamps to make precisely shaped microparticles by a process called “over-stamping” that essentially cuts through the nanoporous layer to free the particles from the substrate. One possible application for microparticles made this way from nanoporous silicon are as anodes in lithium-ion batteries, which could significantly increase their capacity without adding a lot of weight.

Vanderbilt University has applied for a patent on the DIPS method.

Researchers from the University of Pavia and University of Toronto contributed to the research, which was supported by grants from the U.S. Army Research Office, INNESCO project, the National Sciences and Engineering Research Council of Canada, and the National Science Foundation.

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