The invention relates to a thermoelectric module, having an electric insulation, an electric conductor path, one surface of the electric conductor path being attached to a surface of the electrical insulation, and a thermoelectric material, one surface of the thermoelectric material being attached to another surface of the conductor path.

A thermoelectric conversion material made of a polycrystalline material represented by a composition formula (1) shown below and having an MgAgAs type crystal structure is provided. An insulating coat is provided on at least one surface of the polycrystalline material. Composition formula (1): (A.sub.a1Ti.sub.b1).sub.xD.sub.yX.sub.100-x-y, wherein 0.2≦a1≦0.7, 0.3≦b1≦0.8, a1+b1=1, 30≦x≦35, 30≦y≦35 hold, wherein A is at least one element selected from the group consisting of Zr and Hf, D is at least one element selected from the group consisting of Ni, Co, and Fe, and X is at least one element selected from the group consisting of Sn and Sb.

Operations for integrating thermoelectric devices in Fin FET technology may be implemented in a semiconductor device having a thermoelectric device. The thermoelectric device includes a substrate and a fin structure disposed on the substrate. The thermoelectric device includes a first connecting layer and a second connecting layer disposed on opposing ends of the fin structure. The thermoelectric device includes a first thermal conductive structure thermally and a second thermal conductive structure thermally coupled to the opposing ends of the fin structure. The fin structure may be configured to transfer heat from one of the first thermal conductive structure or the second thermal conductive structure to the other thermal conductive structure based on a direction of current flow through the fin structure. In this regard, the current flow may be adjusted by a power circuit electrically coupled to the thermoelectric device.

A cross-plane flexible micro-TEG with hundreds of pairs of thermoelectric pillars formed via electroplating, microfabrication, and substrate transferring processes is provided herein. Typically, fabrication is conducted on a Si substrate, which can be easily realized by commercial production line. The fabricated micro-TEG transferred to the flexible layer from the Si substrate. Fabrication methods provided herein allow fabrication of main TEG components including bottom interconnectors, thermoelectric pillars, and top interconnectors by electroplating. Such flexible micro-TEGs provide high output power density due to high density of thermoelectric pillars and very low internal resistance of electroplated components. The flexible micro-TEG can achieve a power per unit area of 4.5 mW cm.sup.−2 at a temperature difference of ˜50 K, which is comparable to performance of flexible TEGs developed by screen printing. The power per unit weight of flexible TEGs described herein is as high as 60 mW g.sup.−1, which is advantageous for wearable applications.

A semiconductor sintered body comprising a polycrystalline body, wherein the polycrystalline body comprises silicon or a silicon alloy, and the average grain size of the crystal grains constituting the polycrystalline body is 1 μm or less, and the electrical conductivity is 10,000 S/m or higher.

This disclosure provides systems, methods, and apparatus related to thermoelectric polymer aerogels. In one aspect, a method includes depositing a solution on a substrate. The solution comprises a thermoelectric polymer. Solvent of the solution is removed to form a layer of the thermoelectric polymer. The layer is placed in a polar solvent to form a gel comprising the thermoelectric polymer. The gel is cooled to freeze the polar solvent. The gel is placed in a vacuum environment to sublimate the polar solvent from the gel to form an aerogel comprising the thermoelectric polymer.

A method is provided for making a multilayer functional fiber, where the method includes: providing a scaffold fiber; disposing a first electrode layer enclosing the scaffold fiber; disposing a functional layer enclosing the first electrode layer, the functional layer having a functional characteristic varying as a function of longitudinal position along the functional layer; disposing a second electrode layer enclosing the functional layer; and disposing a cladding layer enclosing the second electrode layer. In another aspect, a multilayer functional fiber is provided produced by, for instance, the above-noted method.

An overheat detection system and insulation muff comprising an overheat detection system. The overheat detection system comprises a thermometer, a thermal harvesting module comprising at least one passive radiator, the thermal harvesting module being able to generate electrical energy from the thermal difference between two elements, and a digital module, comprising a power management system, a data treatment system and a wireless transmission system, wherein the electrical energy generated by the thermal harvesting module powers the thermometer and the digital module.

Described is an integrated vertical structure for infrared sensors, Peltier cooling, and thermoelectric generator applications consisting of a thermally insulating layer which is kept at a distance to a substrate by at least two spacers. In addition, the spacers have conductor structures which serve as thermoelectric elements.

A method realizes manufacturing the integrated thermoelectric structure, a method realizes the operation of the integrated thermoelectric structure as a detector, a further method realizes the operation of the integrated thermoelectric structure as a thermoelectric generator, and a method realizes the operation of the integrated thermoelectric structure as a thermoelectric Peltier element.

The present invention provides a method of manufacturing a nanofiber-based thermoelectric generator module, the method comprising: an electrode formation step of forming a plurality of electrodes and a plurality of second electrodes so as to be spaced apart from and opposite to each other in an alternately staggered arrangement relative to each other; a first nanofiber arrangement step of arranging a first nonofiber including an n-type or p-type semiconductor; and a second nanofiber arrangement step of arranging a second nonofiber including a semiconductor of a type different from the type of the semiconductor forming the first nanofiber, a nanofiber-based thermoelectric generator module manufactured by the method, and an electrospinning apparatus of manufacturing nanofibers for the nanofiber-based thermoelectric generator module.