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Batteries/New concepts in Research page 051108
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 The National Science Foundation (NSF) reports on a silicon solution as a  potential for truly long-life battery. Using some of the same manufacturing techniques that produce microchips, researchers have created a porous-silicon diode that may lead to improved betavoltaics.

Such devices convert low levels of radiation into electricity and can have useful lives spanning several decades.

While producing as little as one-thousandth of the power of conventional chemical batteries, the new “BetaBattery” concept is more efficient and potentially less expensive than similar designs and should be easier to manufacture.

If the new diode proves successful when incorporated into a finished battery, it could help power such hard-to-service, long-life systems as structural sensors on bridges, climate monitoring equipment and satellites.

The battery’s staying power is tied to the enduring nature of its fuel, tritium, a hydrogen isotope that releases electrons in a process called beta decay.

The porous-silicon semiconductors generate electricity by absorbing the electrons, just as a solar cell generates electricity by absorbing energy from incoming photons of light.

Supported by grants from the NSF Small Business Innovation Research (SBIR) program, a multi-disciplinary team of researchers from the University of Rochester, the University of Toronto, Rochester Institute of Technology and BetaBatt of Houston, Texas, describe their new diode in the May 13 issue of Advanced Materials.

Researchers have been attempting to convert radiation into electricity since the development of the transistor more than 50 years ago.

Mastering the junctions between relatively electron-rich and electron-poor regions of semiconductor material (p-n junctions) led to many modern electronic products.

Yet, while engineers have been successful at capturing electromagnetic radiation with solar cells, the flat, thin devices have been unable to collect enough beta-decay electrons to yield a viable betavoltaic device.

Adobe Photoshop ImageLead-author Wei Sun of the University of Rochester holds the wafer test fixture the researchers used to test the new porous-silicon diode and its interactions with tritium gas.  The diode is the dark wafer in the center of the top plate.  (Photo is credited to the courtesy of the University of Rochester; BetaBatt, Inc.) +

The BetaBatt will not be the first battery to harness a radioactive source, or even the first to use tritium, but the new cell will have a unique advantage - the half-millimeter-thick silicon wafer into which researchers have etched a network of deep pores.

This structure vastly increases the exposed surface area, creating a device that is 10 times more efficient than planar designs.

“The 3-D porous silicon configuration is excellent for absorbing essentially all the kinetic energy of the source electrons,” says co-author Nazir Kherani of the University of Toronto.

Instead of generating current by absorbing electrons at the outermost layer of a thin sheet, surfaces deep within these porous silicon wafers accommodate a much larger amount of incoming radiation. In early tests, nearly all electrons emitted during the tritium’s beta decay were absorbed.

There were a number of practical reasons for selecting tritium as the source of energy, says co-author Larry Gadeken of BetaBatt - particularly safety and containment.
“Tritium emits only low energy beta particles (electrons) that can be shielded by very thin materials, such as a sheet of paper,” says Gadeken.

“The hermetically-sealed, metallic BetaBattery cases will encapsulate the entire radioactive energy source, just like a normal battery contains its chemical source so it cannot escape.”

Even if the hermetic case were to be breached, adds Gadeken, the source material the team is developing will be a hard plastic that incorporates tritium into its chemical structure. Unlike a chemical paste, the plastic cannot not leak out or leach into the surrounding environment.

Researchers and manufacturers have been producing porous silicon for decades, and it is commonly used for antireflective coatings, light emitting devices, and photon filters for fiber optics.

However, the current research is the first patented betavoltaic application for porous silicon and the first time that 3-D p-n diodes have been created with standard semiconductor industry techniques. “The betavoltaic and photovoltaic applications of 3-D porous silicon diodes will result in an exciting arena of additional uses for this versatile material,” says co-author Philippe Fauchet of the University of Rochester. “This is the first time that uniform p-n junctions have been made in porous silicon, which is exciting from the point of view of materials science,” says Fauchet.

For example, because of its characteristics and photon sensitivity, each diode pore could serve as an individual detector, potentially creating an extremely high-resolution image sensor.

“The ease of using standard semiconductor processing technology to fabricate 3-D p-n junctions was surprising,” adds co-author Karl Hirschman of the Rochester Institute of Technology.

That manufacturing ease is an important breakthrough for increasing production and lowering costs, and it makes the device scalable and versatile for a range of applications.

“The initial applications will be for remote or inaccessible sensors and devices where the availability of long-life power is critical,” says Gadeken.

The BetaBattery may prove better suited to certain tasks than chemical batteries when power needs are limited.

The structures are robust - tolerant to motion and shock, and functional from -148° Fahrenheit (-100° Celsius) to 302° F (150°C) - and may never have to be changed for the lifetime of the device. (Information is coutesty of a press release by the National Science Foundation.  The article reference is W. Sun et al., Adv. Mater. 2005,17, 1230.)
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 (Oct. 2003) Water batteries, a non-polluting form of electricity, could some day power microelectronic devices. Researchers Daniel Kwok and Larry Kostiuk in the mechanical engineering department  at the University of Edmonton in Canada lighted a tiny bulb by squeezing a syringe of ordinary tap water through a glass ‘filter’ having microscopic-size holes. Power was produced by pushing water through  450,000 holes in a small, common glass disc.  Metal electrodes were attached at either end of the device; a wire was connected to  the electrodes which served as a pathway for the current. Although a 30 cm column of water will only produce one to two microAmps, millions of parallel channels could be used to increase the output of power.  For a complete technical description of this fundamental research, see the October 20th edition of the Journal of Micromechanics and Microengineering  published by the London-based Institute of Physics.
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