Theresa S. Mayer received the B.S. degree in Electrical Engineering from Virginia Tech in 1988, and the M.S. and Ph.D. degrees in Electrical Engineering from Purdue University in 1989 and 1993. In 1994, she joined the Department of Electrical Engineering at Penn State University-University Park, where she is a Professor.
Dr. Mayer was appointed as an Associate Director of the Penn State University Materials Research Institute in 2006, where she serves as the Technical Director of Penn State Nanofabrication Facility. She is also the Director of the Penn State Site of the National Science Foundation National Nanotechnology Infrastructure Network (NSF-NNIN). Her interests are in the areas of nanoscale electronic and optical device fabrication, integration, and characterization.
Her group currently has funded projects in semiconductor nanowire electronics, self-assembly of chemical and biological sensors on CMOS chips, metallo- and all-dielectric metamaterials, and molecular electronic devices. Prof. Mayer was a Kodak Fellow (1990-1993) and the recipient of a National Science Foundation CAREER Award (1995), and a Penn State Engineering Society Outstanding Teaching Award (2000).
She served as the General Chair of the IEEE Device Research Conference and the Chair of the Gordon Research Conference on the Chemistry and Physics of Nanostructure Fabrication in 2006. Dr. Mayer holds 5 U.S. Patents and is the co-author of over 90 journal publications. | Bottom-up manufacturing may hold the key to production of tiny medical devices capable of testing for multiple molecules like viruses or cancer markers, according to an interdisciplinary team of Penn State researchers.
"Diagnostic chips can be made more useful by assembling, at predetermined locations on the chip, large numbers of nanowires pretreated off chip," says Rustom B. Bhiladvala, research assistant professor, electrical engineering. "Using this new bottom-up method, our group has demonstrated that thousands of single wires can be successfully aligned and anchored to form tiny diving board resonator arrays."
The traditional top-down process begins with silicon and carves nanoresonator devices from the material. This approach works well and produces many devices that are nearly identical, but the process has limitations. The addition of chemical probes or other changes in the existing materials must be done after the devices are fabricated on the chips.
The bottom-up method, although not producing identical devices, is more flexible. In bottom-up fabrication, researchers manufacture nanowires off chip using any inorganic or organic material that will produce nanowires. They can attach probe molecules to the wires off chip, using a variety of chemicals and they can attach each group of nanowires and their probes to the chips in the numbers and at the locations desired.
"We can achieve high device integration yields, but the devices are not as uniform as top-down manufactured devices," says Theresa S. Mayer, professor of electrical engineering. "However, we can access materials that are not easy to integrate into the devices with top-down methods. We can also integrate wires treated off-chip with entirely different probe molecules that are attached to the wires using condition optimized for that molecule."
The researchers described their bottom-up method using fabrication of a resonator array in the current issue of Nature Nanotechnology. They fabricated these proof-of-concept chips with nanowires made of single crystal silicon or polycrystalline rhodium attached at one end and suspended over a depression. This type of device can detect target molecules when they bind to the probe molecules on the nanowires and change the wire's vibration.
To create the bottom-up diving board resonators, the researchers used a layer of photoresist – a light-sensitive material which, when exposed to light, can then be easily removed chemically – to create an array of tiny rectangular wells on the chip. These wells were aligned above an insulated electrode on the chip surface. A solution of nanowires, with probes already attached, flows over the chip surface while the electrodes produce an electric field. The electric field grabs the nanowires and pulls them to the surface where they align perpendicular to the electrode. The aligned nanowires skate along the electrodes and when they reach a well, drop down into it. |
Once a wire is in a well, that wire repels other wires allowing, for the most part, only one wire per well. The number of wires in the solution is controlled depending on the number of wells so only a few wires remain on the chip outside the wells.
"One of the biggest challenges of self assembly is whether we can control where the wires go and control the defects," says Mayer, associate director of Penn State's Material Research Institute and director of Penn State's site of the National Science Foundation's National Nanotechnology Infrastructure Network. "This new method allows integration of the nanowires with high yield."
In the case of the resonators, once the wires are in the depressions, the researchers switch to a top-down approach, placing a layer of a different photoresist on top of the chip and removing a small cube of photoresist around the tip where the wire anchor will be built. The researchers then electro-deposit metal into the tiny square holes, anchoring the nanowire in place. They dissolve the photoresist, leaving the suspended nanowire and at the same time removing the nanowires that did not make it into wells.
By choosing the well depth and the thickness of the original photoresist layer, the researchers can adjust the height of the resonator above the chip surface. An added benefit of bottom-up fabrication is that the nanowires with their probe molecules retain their functionality after integration. The researchers also showed that, after the resonator chip arrays were fabricated, target molecules did selectively bind to only those nanowires treated with the correct probe molecules.
The researchers tested many silicon and rhodium nanoresonators by measuring their vibration at high vacuum and found that the electroplated anchors were uniform, not too far from rigid and did not show high energy losses. They also found that both types of wires show negligible effects of air damping at pressures as high as about a thousandth of an atmosphere, which can be reached using small and inexpensive vacuum pumps. They showed that both nanowire dimensions and material properties affect the loss due to air damping at one atmosphere. The quality of the response at this modest vacuum is such that these resonators are strong candidates for sensitive resonance-based detection schemes.
"Bottom-up fabrication is an entirely new nanomanufacturing approach and we need to create devices that have properties that match what we can now make using top-down fabrication," says Mayer. "Our vision is to make large arrays of nano size devices with multiple probes for multiple targets by placing different groups of functionalized nanowires sequentially on chips." ###
The researchers included Bhiladvala; Mayer; Mingwei Li, graduate student, electrical engineering; Thomas J. Morrow, graduate student and James A. Sioss, recent Ph.D. recipient, chemistry; Kok-Keong Lew, recent Ph.D. recipient in materials science and engineering; Joan M. Redwing, professor of materials science and engineering and electrical engineering and Christine D. Keating, associate professor of chemistry.
The National Institutes of Health and the NSF provided support for this research. Members of the research team have filed a provisional patent on this assembly process.
Contact: A'ndrea Elyse Messer
aem1@psu.edu 814-865-9481
Penn StateTags:
Nano or
Nanotechnology and
Nanotech or
Penn State and
nanowires or
rhodium nanoresonators
No comments:
Post a Comment