A system, a thermoelectric generator, and a method for generating electricity are provided. The system includes a thermoelectric generator, a cooling system, and a heating system. The cooling system includes a cold side module configured to hold a predetermined volume of air, a subterranean heat exchanger including an underground conduit, the underground conduit having a first end configured to receive ambient air and a second end coupled to the inlet of the cold side module, and an air exhaust coupled to the outlet of the cold side module and having one or more valves configured to control an airflow from the subterranean heat exchanger towards the air exhaust. The heating system includes a first solar concentrator to collect light rays, a hot side module, and a fiber optic cable to transport the collected light rays to the hot side module.

Electrical devices with an integral thermoelectric generator comprising a spin-Seebeck insulator and a spin orbit coupling material, and associated methods of fabrication. A spin-Seebeck thermoelectric material stack may be integrated into macroscale power cabling as well as nanoscale device structures. The resulting structures are to leverage the spin-Seebeck effect (SSE), in which magnons may transport heat from a source (an active device or passive interconnect) and through the spin-Seebeck insulator, which develops a resulting spin voltage. The SOC material is to further convert the spin voltage into an electric voltage to complete the thermoelectric generation process. The resulting electric voltage may then be coupled into an electric circuit.

A thermoelectric conversion device includes: an insulating layer; and a thermoelectric conversion module disposed on the insulating layer. The thermoelectric conversion module has a first thermoelectric conversion region and a second thermoelectric conversion region. The first(second) thermoelectric conversion region includes one or two or more thermoelectric conversion elements, a first(third) connection electrode, and a second(fourth) connection electrode. The thermoelectric conversion elements of the first(second) thermoelectric conversion region are electrically connected to the first(third) connection electrode and the second(fourth) connection electrode and located on an electric path connecting these connection electrodes. Each of the thermoelectric conversion elements includes a thermoelectric converter. The thermoelectric converter of at least one of the thermoelectric conversion elements has a phononic crystal layer having a phononic crystal structure including a plurality of regularly arranged through holes. A through direction of the plurality of through holes in this crystal structure is substantially parallel to a direction perpendicular to a principal surface of the insulating layer.

A thermoelectric conversion device includes: a first thermoelectric conversion module, a first insulating layer, and a second thermoelectric conversion module. The first (second) thermoelectric conversion module includes one or two or more thermoelectric conversion elements, a first (third) connection electrode, and a second (fourth) connection electrode. The thermoelectric conversion elements of the first (second) thermoelectric conversion module are electrically connected to the first (third) connection electrode and the second (fourth) connection electrode and located on an electric path connecting these connection electrodes. Each of the thermoelectric conversion elements includes a thermoelectric converter. The thermoelectric converter of at least one of the thermoelectric conversion elements has a phononic crystal layer having a phononic crystal structure including a plurality of regularly arranged through holes. A through direction of the plurality of through holes in this crystal structure is substantially parallel to a stacking direction of the first thermoelectric conversion module, the first insulating layer, and the second thermoelectric conversion module.

A system, a thermoelectric generator, and a method for generating electricity are provided. The system includes a thermoelectric generator, a cooling system, and a heating system. The cooling system includes a cold side module configured to hold a predetermined volume of air, a subterranean heat exchanger including an underground conduit, the underground conduit having a first end configured to receive ambient air and a second end coupled to the inlet of the cold side module, and an air exhaust coupled to the outlet of the cold side module and having one or more valves configured to control an airflow from the subterranean heat exchanger towards the air exhaust. The heating system includes a first solar concentrator to collect light rays, a hot side module, and a fiber optic cable to transport the collected light rays to the hot side module.

A new class of thermoelectric and energy conversion apparatus, that enhances the efficiency of converting one form of energy to another using a wide range of energy conversion materials. The new method of stimulating greater electrical conversion using polymers and thermoelectric composite materials that have unique properties similar to commercial superconductors. The invention entails processes that create and interconnect the superconducting polymer layers through an assembly lowering internal resistance, impeding phonon conduction and stimulating increase in electron flow through the device with increased electrical power. The invention includes the use of dopants that are mixed with a polymer solution to build superconducting polymer connections between the thermoelectric device layers.

A thermal test head for an integrated circuit device includes a heat exchanger assembly, a contact assembly configured to contact the integrated circuit, and a thermal control assembly disposed between the heat exchanger assembly and the contact assembly. The thermal control assembly includes a Peltier device in thermal contact with opposing surfaces of the heat exchanger assembly and the contact assembly, and a spacer in physical contact with the opposing surfaces of the heat exchanger assembly and the contact assembly.

A thermoelectric cooler including a thermoelectric junction and a radiation source. The thermoelectric cooler includes n-type material, p-type material, and an electrical power source. The radiation source emits ionizing radiation that increases electrical conductivity of the n and p type materials. Also detailed is a method of using radiation to reach high coefficient of performance (COP) values with a thermoelectric cooler that includes providing a thermoelectric cooler and a radiation source, with the thermoelectric cooler including an n-type material, p-type material, an electrical power source, and emitting ionizing radiation with the radiation source to increase the electrical conductivity which strips electrons from 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 generator for a vehicle is provided and includes a thermoelectric material unit having unit thermoelectric materials and movable in a direction in which the thermoelectric material unit approaches a heated body of a vehicle and a direction in which the thermoelectric material unit moves away from the heated body. A thermal expansion member is disposed between the thermoelectric material unit and the heated body and selectively expands or contracts in response to a temperature of the heated body/An elastic member elastically supports a movement of the thermoelectric material unit relative to the heated body.

The technical description relates to energy storage systems and methods. Specific examples described herein relate to in-ground energy storage systems and methods of selectively discharging electrical energy from an energy storage system. An example energy storage system comprises a first fluid storage tank, a second fluid storage tank, a first fluid disposed in the first fluid storage tank, a second fluid disposed in the second fluid storage tank, a heating unit operably connected to the first fluid storage tank and adapted to heat the first fluid, a cooling unit operably connected to the second fluid storage tank and adapted to cool the second fluid, and an energy conversion unit exposed to the first fluid and the second fluid. The energy conversion unit is adapted to convert a temperature difference between the first fluid and the second fluid directly to electrical energy or indirectly to electrical energy through intermediate mechanical work, such as rotational motion.