A nuclear fuel cell includes a net neutron-producing material, a neutron-consuming material, and a neutron-moderating material. Upon exposure of the net-producing material, the neutron-moderating material, and the neutron-consuming material to a neutron source, a ratio of the net neutron-producing material to (i) the neutron-consuming material and (ii) the neutron-moderating material is operable to convert neutrons into charged particles without producing net neutrons.

A nuclear fuel cell includes a net neutron-producing material, a neutron-consuming material, and a neutron-moderating material. Upon exposure of the net-producing material, the neutron-moderating material, and the neutron-consuming material to a neutron source, a ratio of the net neutron-producing material to (i) the neutron-consuming material and (ii) the neutron-moderating material is operable to convert neutrons into charged particles without producing net neutrons.

Systems, methods, and devices for electrical power generation are disclosed. A device includes a radioactive source that emits radiation including at least one of: electrically charged particles; electrically neutral particles; or electromagnetic radiation; an ion media positioned adjacent to the radioactive source, wherein the ion media comprises a material that releases electrons in response to exposure to radiation; a set of two or more electrodes configured to: establish an electric field across the ion media; capture electrons released by the ion media in response to exposure to radiation emitted by the radioactive source; and generate electric current from the captured electrons. The device includes a supplemental power supply electrically connected to the set of two or more electrodes. The device includes an electrical load electrically connected to the set of two or more electrodes.

Systems, methods, and devices for electrical power generation are disclosed. A device includes a radioactive source that emits radiation including at least one of: electrically charged particles; electrically neutral particles; or electromagnetic radiation; an ion media positioned adjacent to the radioactive source, wherein the ion media comprises a material that releases electrons in response to exposure to radiation; a set of two or more electrodes configured to: establish an electric field across the ion media; capture electrons released by the ion media in response to exposure to radiation emitted by the radioactive source; and generate electric current from the captured electrons. The device includes a supplemental power supply electrically connected to the set of two or more electrodes. The device includes an electrical load electrically connected to the set of two or more electrodes.

A chargeable atomic battery (CAB) and a standardized pre-irradiation encapsulation manufacturing method. A CAB unit is manufactured through a non-radioactive process and then placed in a radiation field (typically a fission reactor) to convert a portion of a non-radioactive precursor material into an activated material (e.g., radioisotope) for charging. After charging, the CAB unit is ready for use and can be combined with additional CAB units into a CAB stack to achieve the desired activity and then integrated into a CAB pack or a product that uses the radioactivity for the desired application such as heating, electricity, and passive x-ray sources. The pre-irradiation encapsulation manufacturing method uses a die press and sintering process to produce the CAB unit with the precursor material fully encapsulated by the encapsulation material. During and after the charging process, the encapsulation material serves as a barrier, preventing release of the activated material release.

A chargeable atomic battery (CAB) and a standardized pre-irradiation encapsulation manufacturing method. A CAB unit is manufactured through a non-radioactive process and then placed in a radiation field (typically a fission reactor) to convert a portion of a non-radioactive precursor material into an activated material (e.g., radioisotope) for charging. After charging, the CAB unit is ready for use and can be combined with additional CAB units into a CAB stack to achieve the desired activity and then integrated into a CAB pack or a product that uses the radioactivity for the desired application such as heating, electricity, and passive x-ray sources. The pre-irradiation encapsulation manufacturing method uses a die press and sintering process to produce the CAB unit with the precursor material fully encapsulated by the encapsulation material. During and after the charging process, the encapsulation material serves as a barrier, preventing release of the activated material release.

A chargeable atomic battery (CAB), such as a fully ceramic encapsulated radioactive heat source, includes a plurality of CAB units and a CAB housing to hold the plurality of CAB units. Each of the CAB units are formed of a precursor compact including precursor material particles embedded inside an encapsulation material. The precursor material particles include a precursor kernel formed of a precursor material that is initially manufactured in a stable state or an unstable state and convertible into an activated material via irradiation by a particle radiation source. The precursor material particles can include one or more encapsulation coatings surrounding the precursor kernel. The precursor material can include Neptunium-237 and the activated material can include Plutonium-238. A radioisotope thermoelectric generator can include thermoelectrics coupled to the CAB units to convert radioactive emissions of the activated material into electrical power.

A machine, article, process of using, process of making, products produced thereby and necessary intermediates. Illustratively, there can be a process of producing electrical power, the process comprising: creating neutrons via nuclear reactions, said neutrons carrying neutron kinetic energy; moderating said neutrons to thermal energies to produce moderated neutrons, converting the neutron kinetic energy into heat, and transmitting said heat to a heat exchanger; creating ions via the nuclear reactions, stopping the ions to produce heat, and transmitting to said heat exchanger the heat generated by the stopping of the ions; capturing said moderated neutrons with sulfur atoms to produce heat, and transmitting to said heat exchanger energy released by the capturing of said moderated neutrons; transmitting energy from decaying radioisotopes created by the capturing of said moderated neutrons to said heat exchanger; heat exchanging at least some of each said heat and energy in said heat exchanger by converting water into steam; and generating electrical power with said steam.

Methods and apparatus for converting kinetic energy of an energetic particle into electrical energy and for accelerating charged particles. A stack of substantially parallel conductors separated by gaps is disposed such that the conductors are substantially parallel to the surface of a cathode, with the conductors mutually electrically uncoupled. An anode is disposed at an end of the stack of conductors distal to the cathode, and a power management system applies a bias voltage between the cathode and the anode and collects charge deposited at the anode in the form of current in an external electrical circuit.

Methods and apparatus for converting kinetic energy of an energetic particle into electrical energy and for accelerating charged particles. A stack of substantially parallel conductors separated by gaps is disposed such that the conductors are substantially parallel to the surface of a cathode, with the conductors mutually electrically uncoupled. An anode is disposed at an end of the stack of conductors distal to the cathode, and a power management system applies a bias voltage between the cathode and the anode and collects charge deposited at the anode in the form of current in an external electrical circuit.