Leading experts at the Moscow Institute of Physics (MIPT) have succeeded in producing a prototype nuclear battery that stores 3,300 milliwat hours of energy per gram. Unlike the other batteries, beta-voltaic cells were discovered by the nickel-63 isotope, which yields about 10 times more power than conventional carrier cells.
These new nuclear batteries, called beta batteries, store their power by transforming the energy of beta decay into electricity through the conductors inside. If you look at the basis of this technology we talked about, it stretches back to 1970's. These batteries, which are small in size and feature large energy storage, are mostly used in heart valves. Models with shorter durability and higher power densities were costly, and these pillars were removed due to the preference of cheaper chemical batteries.
Bahsi geçen bu pillerin arka planda kalmasının sebebi elbette yalnızca pahalı olmaları değildi. O zamanlar radyoaktif olan şeylerin halk arasında tehlikeli bulunması ve korkuya neden olması da bir diğer etken olarak ön plana çıkıyor. MIPT ekibi ise nikel-63 kullanarak güç yoğunluğunu, daha önce Rusya ve Bristol’de yapılan testlerden yola çıkarak yeniden ayarladılar. Bariyer tabanlı elmas elektrotlar ve schottky diyotlar ile yeni bir enerji dönüşümü sağlayan uzmanlar, böylece amaçlarına ulaşmış oldular.
200 adet elmas dönüştürü kullanıp nikel-63 ve kararlı izotopu nikel folyo tabakaları ile kesiştiren uzmanlar, folyonun kalınlığına bağlı olarak değişen güç dengesini sabitlemeyi başardılar.
In this new technology developed, the electrons emitted when the foil is too thick can not absorb themselves by themselves. However, when you bring the foil to a very thin state, the deteriorating atoms are decreasing and resistance is increasing. The development team believes that the resistance point needed by nickel-63 foil should be 2 micrometres thick with a 10 micrometer Schottky diode and a diamond transformer using a simulation methodology.
In this new technology developed, the electrons emitted when the foil is too thick can not absorb themselves by themselves. However, when you bring the foil to a very thin state, the deteriorating atoms are decreasing and resistance is increasing. The development team believes that the resistance point needed by nickel-63 foil should be 2 micrometres thick with a 10 micrometer Schottky diode and a diamond transformer using a simulation methodology.
The production of your transformer, of course, included some of its own difficulties. The team created a damaged layer of the ion implantation with boron doped diamond film before the diamond implant, and then placed the plates on a diamond substrate to obtain the condensation. On this count, the top floor could be saved.