A radiation powered device includes a first electrode, a second electrode, a semiconductor disposed between the first and second electrodes, and a radioactive source configured to generate a flow of electrons through the semiconductor between the first and second electrodes, wherein the semiconductor comprises diamond material, wherein the radioactive source is embedded within the diamond material, wherein the radioactive source comprises a beta-emitting radioisotope, and atoms of the radioisotope are either substitutionally or interstitially integrated into the diamond material, wherein the diamond material comprises a plurality of regions in the form of layers within a continuous crystal lattice of the diamond material, and wherein at least one layer of the diamond material comprises the radioactive source and at least one layer of the diamond material does not comprise the radioactive source.

A device for producing electricity. The device comprises a source of tritium radioisotopes, an element Th maintained at a temperature Th, and an element Tc maintained at a temperature Tc; Tc lower than Th. The source generates heat and is disposed in thermal communication with the element Th to maintain the temperature Th. First and second doped elements, each doped with a different dopant type, are oriented in parallel relative to the heat flow path between the element Th and the element Tc and electrically connected in series According to the Seebeck effect, a voltage is generated between the first and second doped elements due to a temperature differential between the Tc and Th, causing current to flow through the serially-connected doped elements. Helium generated during generation of the radioisotopes is vented from the device.

A device for producing electricity. The device comprises a source of tritium radioisotopes, an element Th maintained at a temperature Th, and an element Tc maintained at a temperature Tc; Tc lower than Th. The source generates heat and is disposed in thermal communication with the element Th to maintain the temperature Th. First and second doped elements, each doped with a different dopant type, are oriented in parallel relative to the heat flow path between the element Th and the element Tc and electrically connected in series According to the Seebeck effect, a voltage is generated between the first and second doped elements due to a temperature differential between the Tc and Th, causing current to flow through the serially-connected doped elements. Helium generated during generation of the radioisotopes is vented from the device.

A device for producing electricity. The device includes a substrate having spaced apart first and second surfaces and doped a first dopant type, first semiconductor material layers disposed atop the first substrate surface and doped the first dopant type, and second semiconductor material layers disposed atop the first semiconductor material layers and doped a second dopant type. A first contact is in electrical contact with the second substrate surface or in electrical contact with one of the first semiconductor material layers. A beta particle source emits beta particles that penetrate into the semiconductor material layers; the beta particle source is proximate the uppermost layer of the second plurality of semiconductor material layers. A second contact is in electrical contact with one of the second plurality of semiconductor material layers. In one embodiment, bi-polar contacts (the first and second contacts) are co-located on each major face of the device.

A device for producing electricity. The device includes a substrate having spaced apart first and second surfaces and doped a first dopant type, first semiconductor material layers disposed atop the first substrate surface and doped the first dopant type, and second semiconductor material layers disposed atop the first semiconductor material layers and doped a second dopant type. A first contact is in electrical contact with the second substrate surface or in electrical contact with one of the first semiconductor material layers. A beta particle source emits beta particles that penetrate into the semiconductor material layers; the beta particle source is proximate the uppermost layer of the second plurality of semiconductor material layers. A second contact is in electrical contact with one of the second plurality of semiconductor material layers. In one embodiment, bi-polar contacts (the first and second contacts) are co-located on each major face of the device.

A device for producing electricity. In one embodiment, the device comprises a doped germanium or a doped GaAs substrate and a plurality of stacked material layers (some of which are doped) above the substrate. These stacked material layers, which capture beta particles and generate electrical current, may include, in various embodiments, GaAs, InAlP, InGaP, InAlGaP, AlGaAs, and other semiconductor materials. A radioisotope source generates beta particles that impinge the stack, create electron-hole pairs, and thereby generate electrical current. In another embodiment the device comprises a plurality of epi-liftoff layers and a backing support material. The devices can be connected in series or parallel.

A device for producing electricity. In one embodiment, the device comprises a doped germanium or a doped GaAs substrate and a plurality of stacked material layers (some of which are doped) above the substrate. These stacked material layers, which capture beta particles and generate electrical current, may include, in various embodiments, GaAs, InAlP, InGaP, InAlGaP, AlGaAs, and other semiconductor materials. A radioisotope source generates beta particles that impinge the stack, create electron-hole pairs, and thereby generate electrical current. In another embodiment the device comprises a plurality of epi-liftoff layers and a backing support material. The devices can be connected in series or parallel.

A radiation powered device includes a first electrode, a second electrode, a semiconductor disposed between the first and second electrodes, and a radioactive source configured to generate a flow of electrons through the semiconductor between the first and second electrodes, wherein the semiconductor comprises diamond material, wherein the radioactive source is embedded within the diamond material, wherein the radioactive source comprises a beta-emitting radioisotope, and atoms of the radioisotope are either substitutionally or interstitially integrated into the diamond material, wherein the diamond material comprises a plurality of regions in the form of layers within a continuous crystal lattice of the diamond material, and wherein at least one layer of the diamond material comprises the radioactive source and at least one layer of the diamond material does not comprise the radioactive source.

A radiation powered device includes a first electrode, a second electrode, a semiconductor disposed between the first and second electrodes, and a radioactive source configured to generate a flow of electrons through the semiconductor between the first and second electrodes, wherein the semiconductor comprises diamond material, wherein the radioactive source is embedded within the diamond material, wherein the radioactive source comprises a beta-emitting radioisotope, and atoms of the radioisotope are either substitutionally or interstitially integrated into the diamond material, wherein the diamond material comprises a plurality of regions in the form of layers within a continuous crystal lattice of the diamond material, and wherein at least one layer of the diamond material comprises the radioactive source and at least one layer of the diamond material does not comprise the radioactive source.

A product includes a transparent scintillator material, a beta emitter material having an end-point energy of greater than 225 kiloelectron volts (keV), and a photovoltaic portion configured to convert light emitted by the scintillator material to electricity.