Various aspects include electric generators configured to boost electrical output by leveraging electron avalanche generated by a high energy photon radiation source. In various aspects, an electric generator includes a stator and a rotor positioned within the stator, wherein the stator and rotor are configured to generate electric current when the rotor is rotated, and a high energy photon source (e.g., a gamma ray source) positioned and configured to irradiate at least a portion of conductors in the rotor or stator. In some aspects, the stator generates a magnetic field when the electric generator is operating, and the rotor includes armature windings configured to generate electric current when the rotor is rotated. In some aspects, the high energy photon source includes cobalt-60 and/or cesium-137.

Various aspects include electric generators configured to boost electrical output by leveraging electron avalanche generated by a high energy photon radiation source. In various aspects, an electric generator includes a stator and a rotor positioned within the stator, wherein the stator and rotor are configured to generate electric current when the rotor is rotated, and a high energy photon source (e.g., a gamma ray source) positioned and configured to irradiate at least a portion of conductors in the rotor or stator. In some aspects, the stator generates a magnetic field when the electric generator is operating, and the rotor includes armature windings configured to generate electric current when the rotor is rotated. In some aspects, the high energy photon source includes cobalt-60 and/or cesium-137.

A circuit for cooling is disclosed. The circuit uses a pulse generator in combination with a conductor. A cooling effect of the circuit on the conductor can be used and can be used in conjunction with a Carnot or Stirling engine. A resultant energy applied to a load is larger than the energy supplied by the pulse generator due to the absorption of external energy by the conductor.

A circuit for cooling is disclosed. The circuit uses a pulse generator in combination with a conductor. A cooling effect of the circuit on the conductor can be used and can be used in conjunction with a Carnot or Stirling engine. A resultant energy applied to a load is larger than the energy supplied by the pulse generator due to the absorption of external energy by the conductor.

An object of the present invention is to provide a stable thermoelectric battery. The object can be solved by a thermoelectric battery comprising a working electrode containing a n-type silicon and germanium, a counter electrode, and a solid electrolyte having a polymer having a specific repeating unit with a molecular weight of 200 to 1,000,000, or a derivative thereof, wherein the solid electrolyte contains copper ions or iron ions as an ion source.

An object of the present invention is to provide a stable thermoelectric battery. The object can be solved by a thermoelectric battery comprising a working electrode containing a n-type silicon and germanium, a counter electrode, and a solid electrolyte having a polymer having a specific repeating unit with a molecular weight of 200 to 1,000,000, or a derivative thereof, wherein the solid electrolyte contains copper ions or iron ions as an ion source.

An integrated circuit on a chip may include a plurality of capacitors that are connected in series and generate an AC noise signal. A selected bandwidth of the AC noise signal transmits through the series of capacitors as a first AC power signal. Respective rectifiers are positioned for receiving a positive cycle of the first AC power signal and a negative cycle of the first AC power signal. Output terminals are connected to the respective rectifiers and configured for connection to an off chip circuit. The capacitors may be fixed or variable gap capacitors.

An integrated circuit on a chip may include a plurality of capacitors that are connected in series and generate an AC noise signal. A selected bandwidth of the AC noise signal transmits through the series of capacitors as a first AC power signal. Respective rectifiers are positioned for receiving a positive cycle of the first AC power signal and a negative cycle of the first AC power signal. Output terminals are connected to the respective rectifiers and configured for connection to an off chip circuit. The capacitors may be fixed or variable gap capacitors.

A device for converting thermal energy into electrical energy has a first and second layer of thermally conductive material, and an intermediate layer of polymer material arranged between the first and second layers and having a thermal conductivity lower than the first and the second layers. A plurality of channels in which a colloidal suspension of active particles is contained is arranged inside the intermediate layer, the colloidal suspension being capable of flowing along each of the channels as a result of a temperature gradient applied between the first and second layers. Pick-up elements arranged along the channels are configured to extract electrostatic force or electromotive force induced as a response to a flow of the colloidal fluid as a result of at least one among a pyroelectric effect, a triboelectric effect, and thermomagnetic advection. Each channel forms a closed loop and has an outgoing branch and a return branch.

A device for converting thermal energy into electrical energy has a first and second layer of thermally conductive material, and an intermediate layer of polymer material arranged between the first and second layers and having a thermal conductivity lower than the first and the second layers. A plurality of channels in which a colloidal suspension of active particles is contained is arranged inside the intermediate layer, the colloidal suspension being capable of flowing along each of the channels as a result of a temperature gradient applied between the first and second layers. Pick-up elements arranged along the channels are configured to extract electrostatic force or electromotive force induced as a response to a flow of the colloidal fluid as a result of at least one among a pyroelectric effect, a triboelectric effect, and thermomagnetic advection. Each channel forms a closed loop and has an outgoing branch and a return branch.