A composite including: at least one selected from a silicon oxide of the formula SiO.sub.2 and a silicon oxide of the formula SiO.sub.x wherein 0<x<2; and graphene, wherein the silicon oxide is disposed in a graphene matrix.

Provided is a silicide-based alloy material with which environmental load can be reduced and high thermoelectric conversion performance can be obtained. Provided is a silicide-based alloy material including silicon and ruthenium as main components, in which when the contents of silicon and ruthenium are denoted by Si and Ru, respectively, the atomic ratio of the devices constituting the alloy material satisfies the following:
45 atm %≤Si/(Ru+Si)≤70 atm %
30 atm %≤Ru/(Ru+Si)≤55 atm %.

Provided is a silicide-based alloy material with which environmental load can be reduced and high thermoelectric conversion performance can be obtained. Provided is a silicide-based alloy material including silicon and ruthenium as main components, in which when the contents of silicon and ruthenium are denoted by Si and Ru, respectively, the atomic ratio of the devices constituting the alloy material satisfies the following:
45 atm %≤Si/(Ru+Si)≤70 atm %
30 atm %≤Ru/(Ru+Si)≤55 atm %.

Integrated circuit devices which include a thermoelectric generator which recycles heat generated by operation of an integrated circuit, into electrical energy that is then used to help support the power requirements of that integrated circuit. Roughly described, the device includes an integrated circuit die having an integrated circuit thereon, the integrated circuit having power supply terminals for connection to a primary power source, and a thermoelectric generator structure disposed in sufficient thermal communication with the integrated circuit die so as to derive, from heat generated by the die, a voltage difference across first and second terminals of the thermoelectric generator structure. A powering structure is arranged to help power the integrated circuit, from the voltage difference across the first and second terminals of the thermoelectric generator. The thermoelectric generator can include IC packaging material that is made from thermoelectric semiconductor materials.

A thermoelectric converter including a thermoelectric generator and a radiation source. The thermoelectric generator includes a hot source, a cold source, n-type material, and p-type material. The radiation source emits ionizing radiation that increases electrical conductivity. Also detailed is a method of using radiation to reach high efficiency with a thermoelectric converter that includes providing a thermoelectric generator and a radiation source, with the thermoelectric generator including a hot source, a cold source, n-type material, and p-type material, and emitting ionizing radiation with the radiation source to increase the electrical conductivity which strips electrons in the n-type material, the p-type material, or both the n-type material and p-type material from their nuclei with the electrons then free to move within the material.

A method and device incorporating the use of Zinc Oxide to generate electrical power directly from heat, with minimal or no complex and inefficient mechanical interventions, by making advantageous use of the abundance and low cost of ZnO and its pyroelectric and thermoelectric properties. ZnO is used as a cheap, under-used material for the purpose of converting thermal energy (heat) directly into usable electricity with none or almost none of the mechanical conversion systems generally in use.

A thermoelectric converter including a thermoelectric generator and a radiation source. The thermoelectric generator includes a hot source, a cold source, n-type material, and p-type material. The radiation source emits ionizing radiation that increases electrical conductivity. Also detailed is a method of using radiation to reach high efficiency with a thermoelectric converter that includes providing a thermoelectric generator and a radiation source, with the thermoelectric generator including a hot source, a cold source, n-type material, and p-type material, and emitting ionizing radiation with the radiation source to increase the electrical conductivity which strips electrons in the n-type material, the p-type material, or both the n-type material and p-type material from their nuclei with the electrons then free to move within the material.

A thermoelectric converter including a thermoelectric generator and a radiation source. The thermoelectric generator includes a hot source, a cold source, n-type material, and p-type material. The radiation source emits ionizing radiation that increases electrical conductivity. Also detailed is a method of using radiation to reach high efficiency with a thermoelectric converter that includes providing a thermoelectric generator and a radiation source, with the thermoelectric generator including a hot source, a cold source, n-type material, and p-type material, and emitting ionizing radiation with the radiation source to increase the electrical conductivity which strips electrons in the n-type material, the p-type material, or both the n-type material and p-type material from their nuclei with the electrons then free to move within the material.

A thermoelectric conversion element includes an element body formed of a thermoelectric conversion material of a silicide-based compound, and electrodes each formed on one surface of the element body and the other surface opposite the one surface. The electrodes are formed of a sintered body of a copper silicide, and the electrodes and the element body are directly joined.

A thermoelectric conversion material contains a matrix composed of a semiconductor and nanoparticles disposed in the matrix, and the nanoparticles have a lattice constant distribution Δd/d of 0.0055 or more.