To provide a thermoelectric conversion module member which has a high connecting property between a thermoelectric conversion layer and a diffusion prevention layer and is also excellent in heat resistance.

A thermoelectric conversion module member comprising a thermoelectric conversion layer and a diffusion prevention layer in contact with the above-described thermoelectric conversion layer, wherein the above-described thermoelectric conversion layer is a layer containing a thermoelectric conversion material having a silicon element or a tellurium element, the above-described diffusion prevention layer is a layer containing a metal and the same thermoelectric conversion material as that contained in the above-described thermoelectric conversion layer, and the amount of the above-described thermoelectric conversion material in the above-described diffusion prevention layer is 10 to 50 parts by weight with respect to 100 parts by weight of the above-described metal.

A method of fabricating a thermoelectric converter that includes providing a layer of a Silicon-based material having a first surface and a second surface, opposite to and separated from the first surface by a Silicon-based material layer thickness; forming a plurality of first thermoelectrically active elements of a first thermoelectric semiconductor material having a first Seebeck coefficient, and forming a plurality of second thermoelectrically active elements of a second thermoelectric semiconductor material having a second Seebeck coefficient, wherein the first and second thermoelectrically active elements are formed to extend through the Silicon-based material layer thickness, from the first surface to the second surface; forming electrically conductive interconnections in correspondence of the first surface and of the second surface of the layer of Silicon-based material, for electrically interconnecting the plurality of first thermoelectrically active elements and the plurality of second thermoelectrically active elements, and forming an input electrical terminal and an output electrical terminal electrically connected to the electrically conductive interconnections, wherein the first thermoelectric semiconductor material and the second thermoelectric semiconductor material comprise Silicon-based materials selected among porous Silicon or polycrystalline SiGe or polycrystalline Silicon.

A thermoelectric conversion material made of a sintered body containing a magnesium silicide as a major component includes: a magnesium silicide phase; and a magnesium oxide layer formed on a surface layer of the magnesium silicide phase, in which an aluminum concentrated layer having an Al concentration higher than an aluminum concentration in an inside of the magnesium silicide phase is formed between the magnesium oxide layer and the magnesium silicide phase, and the aluminum concentrated layer has a metallic aluminum phase including aluminum or an aluminum alloy.

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 conversion element that includes a laminated body having a plurality of first thermoelectric conversion portions, a plurality of second thermoelectric conversion portions, and an insulator layer. The first thermoelectric conversion portions and the second thermoelectric conversion portions are alternately arranged in a Y-axis direction and bonded to each other in first regions, and the insulator layer is interposed between the first thermoelectric conversion portions and the second thermoelectric conversion portions in second regions. The insulator layer surrounds a periphery of each of the second thermoelectric conversion portions. A ratio (W2/W1) of a thickness (W2) of the first thermoelectric conversion portion to a thickness (W1) of the second thermoelectric conversion portion in the Y-axis direction is greater than 4 and 11 or less.

The present invention provides apparatuses comprising a plurality of junctions providing a Seebeck effect, configured as alternating hot and cold junctions. The apparatus can be configured such that the cold junctions exhibit a different thermal behavior than the hot junctions in response to incident radiation. The junctions can be connected in series, such that the sum of the Seebeck effect from the plurality of junctions provides a sensitive, inherently calibrated indication of heating of the apparatus responsive to incident radiation, and therefore of the radiation itself.

A semiconductor substrate contains a clathrate compound of the following General Formula (I). The semiconductor substrate includes a variable-composition layer which includes a pn junction and where composition of the clathrate compound varies along a thickness direction. A rate of change in y in the thickness direction of at least a portion of the variable-composition layer is 1×10.sup.−4/μm or more.
A.sub.xB.sub.yC.sub.46-y   (I) In General Formula (I), A represents at least one element selected from the group consisting of Ba, Na, Sr, and K, B represents at least one element selected from the group consisting of Au, Ag, Cu, Ni, and Al, and C represents at least one element selected from the group consisting of Si, Ge, and Sn, x is 7 to 9, and y is 3.5 to 6 or 11 to 17.

Various methods and devices for ultrasensitive infrared photodetection, infrared imaging, and other optoelectronic applications using the plasmon assisted thermoelectric effect in graphene are described. Infrared detection by the photo-thermoelectric uses the generation of a temperature gradient (ΔT) for the efficient collection of the generated hot-carriers. An asymmetric plasmon-induced hot-carrier Seebeck photodetection scheme at room temperature exhibits a remarkable responsivity along with an ultrafast response in the technologically relevant 8-12 μm band. This is achieved by engineering the asymmetric electronic environment of the generated hot carriers on chemical vapor deposition (CVD) grown large area nanopatterned monolayer graphene, which leads to a record ΔT across the device terminals thereby enhancing the photo-thermoelectric voltage beyond the theoretical limit for graphene. The results provide a strategy for uncooled, tunable, multispectral infrared detection.

A thermoelectric module comprising nanostructured SnO and SnO.sub.2, and electrodes arranged between two electrical insulating substrates is described. The nanostructured SnO may be in the form of nanosheets and acting as p-type pillars of the module. The nanostructured SnO.sub.2 may be in the form of nanospheres and acting as n-type pillars of the module. This thermoelectric module is evaluated on the voltage, current, and power of the electricity generated once subjected to a temperature gradient.

The present disclosure is related to structures for and methods for producing thermoelectric devices. The thermoelectric devices include multiple stages of thermoelements. Each stage includes alternating n-type and p-type thermoelements. The stages are sandwiched between upper and lower sets of metal links fabricated on a pair of substrate layers. The metal links electrically connect pairs of n-type and p-type thermoelements from each stage. There may be additional sets of metal links between the multiple stages. The individual thermoelements may be sized to handle differing amounts of electric current to optimize performance based on their location within the multistage device.