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“Atomic battery” with a service life of 10 years
Scientists from the University of Rochester (UK) have achieved some success in the development of a new battery for electronic devices. Its work is based on the conversion of nuclear fission energy into electric current. The service life of the “atomic battery” is already estimated at this stage for decades. In the future, such a power source will be able to work two hundred times longer than existing samples.
The need for power supplies for electronic devices is today higher than ever before, according to Philippe Fauchet, professor of electrical and computer engineering and one of the authors of the project. For five decades, people have been solving the problem of converting the energy of simple nuclear decay into electric current, but until recently the results were of purely academic interest. Finally, researchers have found a way to improve conversion efficiency, which could lead to a new type of battery that can produce energy for years.
First of all, the project is designed for those areas of application in which the energy source is not available for replacement and repair, or access to it is very difficult. Since new batteries can operate reliably for over a decade without being recharged or replaced, they would be an ideal choice for use in medical devices such as pacemakers, implanted defibrillators, and other similar devices. Currently, surgery is required to replace and repair batteries in such devices. Other examples of the use of “long-playing” energy sources are space probes and deep-sea research vehicles.
The principle of operation used in the new battery has been known for fifty years, however, it had no practical application, since the energy output was extremely small. The development of technologies made it possible to bring it to acceptable values, significantly increasing the surface area on which the current is generated. Instead of trying to invent new, more active materials, scientists focused on increasing the area by replacing the flat surface with a volumetric. The current occurs when electrons emitted by a radioactive gas, such as tritium, hit a silicon plate, on the surface of which a p-n junction is formed. The current is very small, say, noticeably lower than that of a conventional solar cell, and this interfered with the practical use of batteries. The problem is that the electrons formed as a result of the decay of gas particles scatter in all directions and only some of them hit the plate. To intercept as many electrons released as a result of decay, scientists decided to cover the flat surface of silicon with peculiar wells, each of which will be filled with radioactive gas. In this case, almost all radiation falls on silicon and is converted into current.
The wells are about one micron in diameter and about 40 microns deep. After the wells are formed by etching, a p-n junction with a thickness of a tenth of a micron is created on their inner surface. The result is a tenfold increase in current compared to a flat surface. Researchers are already working to improve this result, believing that the use of a regular grid structure of wells can give a 160-fold increase in energy output compared to the current result.
There is every chance that the achievement of scientists will reach technical implementation. In any case, the specially created American company BetaBatt Inc. recently received a technology commercialization grant from the National Science Foundation (NSF), which also funded the initial research.