In one embodiment, a method includes forming a plurality of thermocouples coupled in series by forming first metal segments comprising a first metal, each of the first metal segments having a L-shape. The method further includes forming a plurality of deep openings to expose a first contact region of each of the first metal segments, and forming a plurality of shallow openings to expose a second contact region of each of the first metal segments. The method further includes forming second metal segments comprising a second metal over the dielectric layer. The second metal is a different type of metal than the first metal. Each of the second metal segments contacts one of the first contact region of the first metal segments through one of the plurality of deep openings and contacts one of the second contact region of the first metal segments through one of the plurality of shallow openings. The plurality of thermocouples is formed within a building component.

In one embodiment, a method includes forming a plurality of thermocouples coupled in series by forming first metal segments comprising a first metal, each of the first metal segments having a L-shape. The method further includes forming a plurality of deep openings to expose a first contact region of each of the first metal segments, and forming a plurality of shallow openings to expose a second contact region of each of the first metal segments. The method further includes forming second metal segments comprising a second metal over the dielectric layer. The second metal is a different type of metal than the first metal. Each of the second metal segments contacts one of the first contact region of the first metal segments through one of the plurality of deep openings and contacts one of the second contact region of the first metal segments through one of the plurality of shallow openings. The plurality of thermocouples is formed within a building component.

Aspects herein are directed to an apparel thermo-regulatory system that actively heats or cools a wearer. The apparel thermo-regulatory system comprises an apparel item, a dimensionally stable frame comprising at least one aperture that is affixed to an outer-facing surface of the apparel item at a predetermined location, an absorbent material applied to an exposed face of the dimensionally stable frame, and at least one thermoelectric module that is releasably positioned within the aperture of the dimensionally stable frame.

There is provided a far infrared (FIR) sensor device including a substrate, a thermopile structure and a heat absorption layer. The thermopile structure is arranged on the substrate. The heat absorption layer covers upon the thermopile structure, wherein the heat absorption layer has a hollow space which is formed by etching a metal layer in the heat absorption layer.

Integrated thermal sensor having a housing delimiting an internal space. A support region extends through the internal space; a plurality of thermocouple elements are carried by the support region and are electrically coupled to each other. Each thermocouple element is formed by a first and a second thermoelectrically active region of a first and, respectively, a second thermoelectrically active material, the first thermoelectrically active material having a first Seeback coefficient, the second thermoelectrically active material having a second Seeback coefficient, other than the first Seeback coefficient. At least one of the first and second thermoelectrically active regions is a silicon-based material. The first and second thermoelectrically active regions of each thermocouple element are formed by respective elongated regions extending at a mutual distance into the internal space of the housing, from and transversely to the support region.

A method of manufacturing an integrated circuit structure includes forming active regions, forming source/drain regions, and forming conductive segments resulting in a thermoelectric structure including a p-type region positioned on a front side of the substrate, an n-type region positioned on the front side of the substrate, and a wire on the front side of the substrate configured to electrically couple the p-type region to the n-type region. The method includes forming a first via configured to thermally couple the p-type region to a first power structure on a back side of the substrate, forming a second via configured to thermally couple the n-type region to a second power structure on the back side of the substrate, and electrically coupling an energy device to each of the first and second power structures.

Techniques are provided for forming one or more thermoelectric devices integrated within a substrate of an integrated circuit. Backside substrate processing may be used to form adjacent portions of the substrate that are doped with alternating dopant types (e.g., n-type dopants alternating with p-type dopants). The substrate can then be etched to form pillars of the various n-type and p-type portions. Adjacent pillars of opposite dopant type can be electrically connected together via a conductive layer. Additionally, the top portions of adjacent pillars are connected together, and the bottom portions of a next pair of adjacent pillars being coupled together, in a repeating pattern to ensure that current flows through the length of each of the doped pillars. The flow of current through alternating n-type and p-type doped material creates a heat flux that transfers heat from one end of the integrated thermoelectric device to the other end.

A monolithically integrated, tunable infrared pixel comprises a combined broadband detector and graphene-enabled tunable metasurface filter that operate as a single solid-state device with no moving parts. Functionally, tunability results from the plasmonic properties of graphene that are acutely dependent upon the carrier concentration within the infrared. Voltage induced changes in graphene's carrier concentration can be leveraged to change the metasurface filter's transmission thereby altering the “colors” of light reaching the broadband detector and hence its spectral responsivity. The invention enables spectrally agile infrared detection with independent pixel-to-pixel spectral tunability.

Aspects relate to an energy harvesting device adapted for use by an athlete while exercising. The device may utilize a mass of phase-change material to store heat energy, the stored heat energy subsequently converted into electrical energy by one or more thermoelectric generator modules. The energy harvesting device may be integrated into an item of clothing, and such that the mass of phase change material may store heat energy as the item of clothing is laundered.

An integrated circuit system, structure and/or component is provided that includes an integrated electrical power source in a form of a unique, environmentally-friendly energy harvesting element or component. The energy harvesting component provides a mechanism for generating autonomous renewable energy, or a renewable energy supplement, in the integrated circuit system, structure and/or component. The energy harvesting element includes a first conductor layer, a low work function layer, a dielectric layer, and a second conductor layer that are particularly configured to promote electron migration from the low work function layer, through the dielectric layer, to the facing surface of the second conductor layer in a manner that develops an electric potential between the first conductor layer and the second conductor layer. An energy harvesting component includes a plurality of energy harvesting elements electrically connected to one another to increase a power output of the electric harvesting component.