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Nanogenerator Converts Tiny Movements to Electric Current

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ATLANTA, April 6, 2007 -- A prototype nanometer-scale generator -- an array of tiny filaments that converts the smallest motions into electrical current -- could free nanomachines from the bulk of batteries by harvesting mechanical energy from such environmental sources as ultrasonic waves, mechanical vibration or even blood flow.GaTechWang.jpg
Georgia Institute of Technology researcher Zhong Lin Wang holds a prototype nanogenerator that was fabricated using an array of zinc oxide nanowires. Wang is a Regents Professor in the Georgia Tech School of Materials Science and Engineering. (Georgia Tech Photo: Gary Meek)
The nanowires are crafted from zinc oxide, a safe material that would allow the generator to be used in biomedical applications, and may eventually power nanomotors, tiny sensors, and if in large enough arrays, macroscale devices without batteries or other external power sources.

"This is a major step toward a portable, adaptable and cost-effective technology for powering nanoscale devices," said Zhong Lin Wang, Regents' Professor in the School of Materials Science and Engineering at the Georgia Institute of Technology. "There has been a lot of interest in making nanodevices, but we have tended not to think about how to power them. Our nanogenerator allows us to harvest or recycle energy from many sources to power these devices."

The nanogenerators take advantage of the unique coupled piezoelectric and semiconducting properties of zinc oxide nanostructures, which produce small electrical charges when they are flexed.nanogenerator.jpg
A prototype nanogenerator was fabricated using an array of zinc oxide nanowires. The nanogenerator was developed by a team of researchers led by Zhong Lin Wang, a Regents Professor in the Georgia Tech School of Materials Science and Engineering.(Georgia Tech Photo: Gary Meek)
Fabrication begins with growing an array of vertically-aligned nanowires approximately a half-micron apart on gallium arsenide, sapphire or a flexible polymer substrate. A layer of zinc oxide is grown on top of substrate to collect the current. The researchers also fabricate silicon "zigzag" electrodes, which contain thousands of nanometer-scale tips made conductive by a platinum coating.

The electrode is then lowered on top of the nanowire array, leaving just enough space so that a significant number of the nanowires are free to flex within the gaps created by the tips. Moved by mechanical energy such as waves or vibration, the nanowires periodically contact the tips, transferring their electrical charges. By capturing the tiny amounts of current produced by hundreds of nanowires kept in motion, the generators produce a direct current output in the nano-Ampere range.

Wang and his group members Xudong Wang, Jinhui Song and Jin Liu expect that with optimization, their nanogenerator could produce as much as 4 W per cubic centimeter -- based on a calculation for a single nanowire. That would be enough to power a broad range of nanometer-scale defense, environmental and biomedical applications, including biosensors implanted in the body, environmental monitors -- and even nanoscale robots.

Nearly a year ago Wang's research team announced the concept behind the nanogenerators. At that time, the nanogenerator could harvest power from just one nanowire at a time by dragging the tip of an atomic force microscope (AFM) over it. Made of platinum-coated silicon, the tip served as a Schottky barrier, helping accumulate and preserve the electrical charge as the nanowire flexed -- and ensuring that the current flowed in one direction.

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With its multiple conducting tips similar to those of an AFM, the new zigzag electrode serves as a Schottky barrier to hundreds or thousands of wires simultaneously, harvesting energy from the nanowire arrays.Nanogeneratorschematic.jpg
Schematic shows the direct current nanogenerator built using aligned ZnO nanowire arrays with a zigzag top electrode. The nanogenerator is driven by an external ultrasonic wave or mechanical vibration and the output current is continuous.
"Producing the top electrode as a single assembly sets the stage for scaling up this technology," Wang said. "We can now see the steps involved in moving forward to a device that can power real nanometer-scale applications."

Before that happens, additional development will be needed to optimize current production. For instance, though nanowires in the arrays can be grown to approximately the same length -- about 1 µm -- there is some variation. Wires that are too short cannot touch the electrode to produce current, while wires that are too long cannot flex to produce electrical charge.

"We need to be able to better control the growth, density and uniformity of the wires," Wang said. "We believe we can make as many as millions or even billions of nanowires produce current simultaneously. That will allow us to optimize operation of the nanogenerator."

In their lab, the researchers aimed an ultrasound source at their nanogenerator to measure current output over slightly more than an hour. Though there is some fluctuation in output, the current flow was continuous as long as the ultrasonic generator was operating, Wang said.

To rule out other sources of the current measured, the researchers substituted carbon nanotubes – which are not piezoelectric – for the zinc oxide nanowires, and used a top electrode that was flat. In both cases, the resulting devices did not produce current.

Providing power for nanometer-scale devices has long been a challenge. Batteries and other traditional sources are too large, and tend to negate the size advantages of nanodevices. And since batteries contain toxic materials such as lithium and cadmium, they cannot be implanted into the body as part of biomedical applications.

Because zinc oxide is nontoxic and compatible with the body, the new nanogenerators could be integrated into implantable biomedical devices to wirelessly measure blood flow and blood pressure within the body. And they could also find more ordinary applications.

"If you had a device like this in your shoes when you walked, you would be able to generate your own small current to power small electronics,”"Wang noted. "Anything that makes the nanowires move within the generator can be used for generating power. Very little force is required to move them."

Details of the nanogenerator are reported in the April 6 issue of the journal Science. The research was sponsored by DARPA, the National Science Foundation and the Emory-Georgia Tech Center of Cancer Nanotechnology Excellence.

For more information, visit: www.mse.gatech.edu

Published: April 2007
Glossary
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
piezoelectric
Piezoelectricity is a property exhibited by certain materials in which they generate an electric charge in response to mechanical stress or deformation, and conversely, undergo mechanical deformation when subjected to an electric field. This phenomenon was discovered by Pierre and Jacques Curie in the late 19th century. The word piezoelectric originates from the Greek word "piezo," meaning to squeeze or press. The effect occurs due to the unique crystal structure of piezoelectric...
sensor
1. A generic term for detector. 2. A complete optical/mechanical/electronic system that contains some form of radiation detector.
ultrasonic
Ultrasonic refers to sound waves with frequencies higher than the upper audible limit of human hearing, typically above 20,000 Hz. These waves are termed ultrasonic because they are beyond the range of frequencies that the human ear can perceive. Ultrasonic waves propagate similarly to audible sound waves but at a higher frequency, which means they have shorter wavelengths. Ultrasonic waves have various applications across different fields due to their unique properties, including: ...
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