Gardeners often use sheets of plastic with strategically placed holes to allow their plants to grow but keep weeds from taking root.
Scientists from UCLA's California NanoSystems Institute have found that the same basic approach is an effective way to place molecules in the specific patterns they need within tiny nanoelectronic devices. The technique could be useful in creating sensors that are small enough to record brain signals.
Led by Paul Weiss, a distinguished professor of chemistry and biochemistry, the researchers developed a sheet of graphene material with minuscule holes in it that they could then place on a gold substrate, a substance well suited for these devices. The holes allow molecules to attach to the gold exactly where the scientists want them, creating patterns that control the physical shape and electronic properties of devices that are 10,000 times smaller than the width of a human hair.
The research is described in "Holey Graphene as a Weed Barrier for Molecules," published in the journal ACS Nano.
"We wanted to develop a mask to place molecules only where we wanted them on a stencil on the underlying gold substrate," Weiss says. "We knew how to attach molecules to gold as a first step toward making the patterns we need for the electronic function of nanodevices. But the new step here was preventing the patterning on the gold in places where the graphene was. The exact placement of molecules enables us to determine exact patterning, which is key to our goal of building nanoelectronic devices like biosensors."
With the advance, making nanoelectronic and nanobioelectronic devices could be much more efficient than current methods of molecular patterning, which use a technique called nanolithography. That could be especially useful for scientists who are trying to place molecular sensors on the surface of gold or other nanomaterials that are used for their sensitivity and selectivity but difficult to work with because of their size, Weiss says.
Neurosensors that could measure brain cell and circuit function in real time could reveal new insights into diseases like autism and depression. Ultimately, Weiss says, the researchers hope to be able to stimulate individual brain circuits using sensors so they can predict key chemical differences between function and malfunction in the brain. This knowledge could then be used to develop targets for new generations of treatments for neurological diseases.
The ACS Nano paper's other authors are John Thomas, Shan Jiang, Nathan Weiss, and Xiangfeng Duan of UCLA, and Matthew Gethers and William Goddard III of Caltech.
Research for the study was conducted in the Electron Imaging Center for Nanomachines and the Nano and Pico Characterization Laboratory, which are both parts of the California NanoSystems Institute.
The research was supported by the U.S. Department of Energy, the U.S. National Science Foundation, the Caltech EAS Discovery Fund, and UCLA.
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