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A betavoltaic power source for transportation devices and applications is disclosed, wherein the device having a stacked configuration of isotope layers and energy conversion layers. The isotope layers have a half-life of between about 0.5 years and about 5 years and generate radiation with energy i

A betavoltaic power source for transportation devices and applications is disclosed, wherein the device having a stacked configuration of isotope layers and energy conversion layers. The isotope layers have a half-life of between about 0.5 years and about 5 years and generate radiation with energy in the range from about 15 keV to about 200 keV. The betavoltaic power source is configured to provide sufficient power to operate the transportation device over its useful lifetime.

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1. A betavoltaic power source that generates electrical energy for a transportation device, comprising: a plurality of isotope layers, each isotope layer including an isotope that emits radiation having energy, and wherein each isotope in the isotope layers is selected from the group of isotopes com

1. A betavoltaic power source that generates electrical energy for a transportation device, comprising: a plurality of isotope layers, each isotope layer including an isotope that emits radiation having energy, and wherein each isotope in the isotope layers is selected from the group of isotopes comprising: (3)H, (194)Os, (228)Ra, (155)Eu, (147)Pm, (171)Tm, (172)Hf, (179)Ta, (109)Cde, (106)Ru, (68)Ge, (195)Au, (45)Ca, (139)Ce and (181)W; anda plurality of energy conversion layers interposed between some or all the isotope layers and that receive and convert the energy from the radiation into the electrical energy to power the transportation device, wherein the plurality of isotope layers and the plurality of energy conversion layers define a stack having a perimeter;a plurality of continuous cooling conduits defined by thermally conducting rods that reside inboard of the perimeter and that pass through the stack so that heat generated within the stack is drawn out of the stack through ends of the rods; andwherein the amount of electrical energy generated is at least 100 W. 2. The betavoltaic power source according to claim 1, wherein the energy conversion layers comprise GaN. 3. The betavoltaic power source according to claim 1, wherein the energy conversion layers each have a thickness of about 10 microns to 20 microns. 4. The betavoltaic power source according to claim 1, further comprising a radiation-absorbing shield operably arranged to prevent the beta particles, x-rays and gamma rays from exiting the betavoltaic power source. 5. The betavoltaic power source according to claim 1, wherein adjacent isotope and energy conversion layers define layer pairs and wherein the betavoltaic power source includes between 500 and 10,000 layer pairs. 6. The betavoltaic power source according to claim 1, wherein the isotope layers are made of the same isotope material. 7. The betavoltaic power source according to claim 1, further comprising the transportation device electrically connected to the betavoltaic power source. 8. A betavoltaic power source that generates electrical energy for use by a transportation device, comprising: a plurality of isotope layers, with each isotope layer comprising an isotope material that emits radiation having an amount of energy that is greater than 15 keV and less than 200 keV, and a half-life that is between 0.5 years and 5 years; anda plurality of energy conversion layers interposed between some or all the isotope layers and that receive and convert the amount of energy from the radiation into the electrical energy which generates no less than 100 watts to power the transportation device. 9. The betavoltaic power source according to claim 8, wherein one or more of the energy conversion layers have a diode structure. 10. The betavoltaic power source according to claim 9, wherein the diode structure includes either GaN or Ge. 11. The betavoltaic power source according to claim 10, wherein the Ge comprises (68)Ge. 12. The betavoltaic power source according to claim 8, wherein adjacent isotope and energy conversion layers define layer pairs, and wherein the betavoltaic power source includes between 500 and 10,000 layer pairs. 13. The betavoltaic power source according to claim 8, wherein the isotope layers are formed from the same isotope material. 14. The betavoltaic power source according to claim 8, wherein the radiation includes at least one of beta particles, x-rays and gamma rays. 15. The betavoltaic power source according to claim 8, further comprising the transportation device electrically connected to the betavoltaic power source. 16. The betavoltaic power source according to claim 8, further comprising a battery electrically connected to the betavoltaic power source. 17. A transportation device electrically connected to the betavoltaic power source according to claim 8. 18. The betavoltaic power source according to claim 8, wherein each isotope in the isotope layers is selected from the group of isotopes comprising: (3)H, (194)Os, (228)Ra, (155)Eu, (147)Pm, (171)Tm, (172)Hf, (179)Ta, (109)Cd, (106)Ru, (68)Ge, (195)Au, (45)Ca, (139)Ce and (181)W. 19. The betavoltaic power source according to claim 8, wherein the plurality of isotope layers and the plurality of energy conversion layers define a stack having a perimeter, and wherein the betavoltaic power source further comprises: a plurality of continuous cooling conduits defined by thermally conducting rods that reside inboard of the perimeter and that pass through the stack so that heat generated within the stack is drawn out of the stack through ends of the rods.