Patent Number: 
Section: claims

1. A radioisotope-powered energy source comprising:a flexible center substrate coated with the radioisotope, wherein the substrate comprises upper and lower surfaces; andtwo substantially identical sequences of layers bonded to the substrate via electrically insulating mesh barriers, one of the sequences being bonded to the upper surface and the other sequence being bonded to the lower surface, wherein the constituent layers of each sequence are bonded to each other via electrically insulating mesh barriers, wherein each sequence comprises the following layers bonded together in the following order:a first low-density alpha particle impact layer,a first high-density beta particle impact layer, anda photovoltaic layer. 2. The energy source of claim 1, wherein each sequence further comprises the following layers interposed between the first beta particle impact layer and the photovoltaic layer:a second low-density alpha particle impact layer,a second radioisotope-coated substrate,a third low-density alpha particle impact layer, anda second high-density beta particle impact layer. 3. The energy source of claim 1, wherein all constituent layers of the energy source are rolled into a cylindrical shape. 4. The energy source of claim 3, wherein each photovoltaic, alpha particle impact, and beta particle impact layer is electrically connected to a capacitor. 5. The energy source of claim 3, wherein the radioisotope is depleted uranium. 6. The energy source of claim 3, wherein the radioisotope is a radioisotope from the Thorium series. 7. The energy source of claim 3, wherein the radioisotope is a radioisotope from the Neptunium series. 8. The energy source of claim 3, wherein the radioisotope is an artificially created radioisotope. 9. The energy source of claim 3, wherein each beta particle impact layer is a beryllium film. 10. The energy source of claim 3, wherein each beta particle impact layer is a carbon film. 11. The energy source of claim 3, wherein each beta particle impact layer is a silver film. 12. The energy source of claim 3, wherein each beta particle impact layer is a gold film. 13. The energy source of claim 3, wherein each alpha particle impact layer is a sodium beta-alumina device. 14. The energy source of claim 3, wherein each alpha particle impact layer is a gallium arsenide diode. 15. The energy source of claim 3, wherein each alpha particle impact layer is a diamond film. 16. A radioisotope-powered energy source comprising:a flexible center substrate coated with the radioisotope, wherein the substrate comprises upper and lower surfaces;first and second electrically insulating mesh barriers coupled to the upper and lower surfaces respectively;first and second low-density alpha particle impact layers coupled to the first and second mesh barriers respectively;third and fourth electrically insulating mesh barriers coupled to the first and second alpha particle impact layers respectively; andfirst and second high-density beta particle impact layers coupled to the third and fourth mesh barriers respectively;fifth and sixth electrically insulating mesh barriers coupled to the first and second beta particle impact layers; andfirst and second photovoltaic layers coupled to the third and fourth electrically insulating mesh barriers. 17. The energy source of claim 16, further comprising the following layers which are interposed between the fifth and sixth mesh barriers and the first and second photovoltaic layers respectively:third and fourth alpha particle impact layers coupled to the fifth and sixth mesh barriers respectively;seventh and eighth electrically insulating mesh barriers coupled to the third and fourth alpha particle impact layers respectively;second and third flexible substrates coated with the radioisotope, wherein the second and third substrates are coupled to the seventh and eighth mesh barriers respectively;ninth and tenth electrically insulating mesh barriers coupled to the second and third substrates respectively;fifth and sixth alpha particle impact layers coupled to the ninth and tenth mesh barriers respectively;eleventh and twelfth electrically insulating mesh barriers coupled to the fifth and sixth alpha particle impact layers respectively; andthird and fourth beta particle impact layers coupled to the eleventh and twelfth mesh barriers respectively and to the first and second photovoltaic layers respectively. 18. A depleted uranium energy source comprising:a flexible center layer of the depleted uranium, wherein the center layer comprises upper and lower surfaces; andtwo substantially identical sequences of layers bonded to the center layer via electrically insulating mesh barriers, one of the sequences being bonded to the upper surface and the other sequence being bonded to the lower surface, wherein the constituent layers of each sequence are bonded to each other via electrically insulating mesh barriers, wherein each sequence comprises the following layers bonded together in a y-direction in the following order:a first low-density alpha particle impact layer,a first high-density beta particle impact layer,a second low-density alpha particle impact layer,a second depleted-uranium-coated substrate,a third low-density alpha particle impact layer,a second high-density beta particle impact layer, anda photovoltaic layer. 19. The depleted uranium energy source of claim 18, wherein the total thickness of the energy source in the y-direction is smaller than the width or length of the energy source in x- and z-directions, and wherein the energy source is rolled into a cylindrical shape.