Abstract: A thermoelectric generator unit according to this disclosure includes a plurality of tubular thermoelectric generators, each of which generates electromotive force based on a difference in temperature between the inner and outer peripheral surfaces. The unit further includes a plurality of electrically conductive members providing electrical connection for the generators and a container housing the generators inside. The container includes a shell surrounding the generators and a pair of plates, at least one of which has a plurality of openings and channels. Each channel houses an electrically conductive member. The generators are electrically connected together in series via the electrically conductive member. At least one of the channels has an interconnection which connects at least two of the openings together and a testing hole portion. The testing hole portion runs from the interconnection through an outer edge of the at least one plate.

Abstract: An exemplary thermoelectric generator unit according to the present disclosure includes a plurality of tubular thermoelectric generators. Each generator generates electromotive force in an axial direction based on a difference in temperature between its inner and outer peripheral surfaces. The unit further includes a container housing the generators inside and a plurality of electrically conductive members providing electrical interconnection among the generators. The container has fluid inlet and outlet ports through which a fluid flows inside the container, and a plurality of openings into which the respective generators are inserted. In one implementation, the unit includes a baffle, which is provided between the fluid inlet port and the generators and changes the flow direction of the fluid that has flowed into the container through the fluid inlet port.

Abstract: A thermoelectric generator system according to this disclosure includes a thermoelectric generator unit which performs thermoelectric generation using first and second heat transfer media at different temperatures. The unit includes a tubular thermoelectric generator which generates electromotive force in its axial direction based on a temperature difference between its inner and outer surfaces. The generator system further includes a flow rate control system which controls the flow rate of at least one of the first heat transfer medium flowing through a flow path defined by the inner surface and the second heat transfer medium in contact with the outer surface by reference to either information about an operation condition of the generator system or a preset target power output level.

Abstract: An exemplary thermoelectric generator disclosed herein includes: a first electrode and a second electrode opposing each other; and a stacked body having a first end face and a second end face. The stacked body is structured so that first layers made of a first material and second layers made of a second material are alternately stacked, the first material containing a metal and particles having a lower thermal conductivity than that of the metal, the particles being dispersed in the metal, and the second material having a higher Seebeck coefficient and a lower thermal conductivity than those of the first material. Planes of stacking between the first layers and the second layers are inclined with respect to a direction in which the first electrode and the second electrode oppose each other.

Abstract: A terahertz electromagnetic wave generator according to the present disclosure includes: a thermoelectric material layer; a metal layer which partially covers the surface of the thermoelectric material layer; and a light source system which is configured to irradiate both a surface region of the thermoelectric material layer that is not covered with the metal layer and an edge of the metal layer with pulsed light, thereby generating a terahertz wave from the thermoelectric material layer.

Abstract: A terahertz electromagnetic wave generator according to the present disclosure includes: a substrate; a thermoelectric material layer which is supported by the substrate and which has a surface; and a pulsed laser light source system which locally heats the thermoelectric material layer with an edge of the surface of the thermoelectric material layer irradiated with pulsed light, thereby generating a terahertz electromagnetic wave from the thermoelectric material layer.

Abstract: A terahertz electromagnetic wave generator according to the present disclosure includes: a thermoelectric material layer; and a light source system which is configured to irradiate the thermoelectric material layer with pulsed light and generate a terahertz wave from the thermoelectric material layer. The thermoelectric material layer includes a gradient portion in which transmittance of the pulsed light varies in a certain direction. And the light source system is configured to irradiate the gradient portion of the thermoelectric material layer with the pulsed light.

Abstract: A method for polarizing an electromagnetic wave having a frequency of not less than 0.1 THz and not more than 0.8 THz using a polarizer includes steps (a) and (b). The step (a) includes preparing the polarizer. The polarizer includes: a sapphire single crystalline layer; and a CaxCoO2 crystalline layer. The CaxCoO2 crystalline layer is stacked on the sapphire single crystalline layer, a surface of the CaxCoO2 crystalline layer has a (100) plane orientation and the CaxCoO2 crystalline layer has a thickness of not less than 2 micrometers and not more than 20 micrometers. The step (b) includes irradiating the polarizer with the electromagnetic wave having a frequency of not less than 0.1 THz and not more than 0.8 THz to output an output wave having only a component parallel to a c-axis direction of the sapphire single crystalline layer.

Abstract: A thermoelectric power generation device includes: a that vessel has an inlet through which a first fluid is introduced and an outlet through which the first fluid is discharged; a tubular thermoelectric element that has a flow-through path through which a second fluid having a temperature different from that of the first fluid flows; a pair of flow path members each penetrating a wall of the vessel while being electrically insulated from the vessel; and lead wires. The flow path members are connected to ends of the thermoelectric element. The flow path members each have a conductive portion extending from a connecting portion between the flow path member and the thermoelectric element to the outside of the vessel. The lead wires each are connected to the conductive portion in the outside of the vessel.

Abstract: A plurality of first cup-shaped members and a plurality of second cup-shaped members are placed alternately in repetition to form a pipe having an inner through-hole. At this point, neither the first cup-shaped members nor the second cup-shaped members are sintered yet. Then, the resultant pipe is sintered to obtain a pipe-shaped thermal power generation device. While the pipe is sintered, a pressure is applied to the pipe along a longitudinal direction of the pipe in a direction in which the pipe is compressed.

Abstract: A gas sensor includes a catalyst layer and a pipe-shaped thermoelectric power generation device. The pipe-shaped thermoelectric power generation device includes an internal through-hole along the axial direction of the pipe-shaped thermoelectric power generation device, a plurality of first cup-shaped components each made of metal, a plurality of second cup-shaped components each made of thermoelectric material, and first and second electrodes disposed at the ends of the pipe-shaped power generation device. The plurality of the first cup-shaped components and the plurality of the plurality of second cup-shaped components are arranged alternately and repeatedly along the axial direction. The catalyst layer is arranged on the internal surface of the internal through-hole. A method for detecting or measuring gas by using the gas sensor includes supplying a fluid containing the gas into the internal through-hole of the gas sensor, and detecting voltage between the first and second electrodes.

Abstract: This disclosure provides a new method for polarizing an electromagnetic wave having a frequency of not less than 0.1 THz and not more than 0.8 THz using a polarizer. The method comprises: a step (a) of preparing the polarizer; wherein the polarizer comprises a sapphire single crystalline layer and a CaxCoO2 crystalline layer, the CaxCoO2 crystalline layer is stacked on the sapphire single crystalline layer, a surface of the CaxCoO2 crystalline layer has a (010) surface orientation, and the CaxCoO2 crystalline layer has a thickness of not less than 2 micrometers and not more than 20 micrometers; and a step (b) of irradiating the polarizer with the electromagnetic wave having a frequency of not less than 0.1 THz and not more than 0.8 THz to output an output wave having only a component parallel to a c-axis direction of the sapphire single crystalline layer.

Abstract: The thermoelectric power generation element includes a first electrode and a second electrode that are disposed to oppose each other, and a laminate that is interposed between the first and second electrodes, where the laminate has a structure in which Bi2Te3 layers and metal layers containing Ni or Co are laminated alternately, a thickness ratio between the metal layer and the Bi2Te3 layer is in a range of metal layer:Bi2Te3 layer=20:1 to 0.5:1, lamination surfaces of the Bi2Te3 layers and the metal layers are inclined at an inclination angle ? of 10° to 60° with respect to a direction in which the first electrode and the second electrode oppose each other, and a temperature difference generated in a direction perpendicular to the direction in the element generates a potential difference between the first and second electrodes.

Abstract: The present invention is drawn to a method for polarizing an electromagnetic wave having a frequency of not less than 0.1 THz and not more than 0.8 THz using a polarizer, the method comprising a step (a) of preparing the polarizer; wherein the polarizer comprises: a sapphire single crystalline layer; and a CaxCoO2 crystalline layer; the CaxCoO2 crystalline layer is stacked on the sapphire single crystalline layer; a surface of the CaxCoO2 crystalline layer has a (100) plane orientation; and the CaxCoO2 crystalline layer has a thickness of not less than 2 micrometers and not more than 20 micrometers, and a step (b) of irradiating the polarizer with the electromagnetic wave having a frequency of not less than 0.1 THz and not more than 0.8 THz to output an output wave having only a component parallel to a c-axis direction of the sapphire single crystalline layer.

Abstract: A pipe-shaped thermoelectric power generating device includes an internal through-hole along the axis direction of the pipe-shaped thermoelectric power generation device; a plurality of first cup-shaped components each made of metal; a plurality of second cup-shaped components each made of thermoelectric material; a first electrode; a second electrode. The plurality of first cup-shaped components and the plurality of second cup-shaped components are arranged alternately and repeatedly along the axis direction. The first electrode and the second electrode are provided respectively at one end and at the other end of the pipe-shaped thermoelectric power generation device.

Abstract: The present invention provides a thermoelectric conversion material composed of an oxide material represented by chemical formula A0.8-1.2Ta2O6-y, where A is calcium (Ca) alone or calcium (Ca) and at least one selected from magnesium (Mg), strontium (Sr), and barium (Ba), and y is larger than 0 but does not exceed 0.5 (0<y?0.5).

Abstract: A radiation detector with high detection sensitivity. The radiation detector according to the present invention includes an Al2O3 substrate, a Fe2O3 thin film layered on the Al2O3 substrate, a CaxCoO2 (where 0.15<x<0.55) thin film that is layered on the Fe2O3 thin film and that has CoO2 planes that are aligned inclined to the surface of the Al2O3 substrate, a first electrode disposed on the CaxCoO2 thin film, and a second electrode disposed on the CaxCoO2 thin film in a position opposed to the first electrode in the direction in which the CoO2 planes are aligned inclined.

Abstract: The thermoelectric device of the present invention includes a first electrode and a second electrode that are disposed to be opposed to each other, and a laminate that is interposed between the first electrode and the second electrode, is connected electrically to both the first electrode and the second electrode, and is layered in the direction orthogonal to an electromotive-force extracting direction, which is the direction in which the first electrode and the second electrode are opposed to each other.

Abstract: The present invention provides a thermoelectric conversion material composed of an oxide material represented by chemical formula A0.8-1.2Ta2O6-y, where A is calcium (Ca) alone or calcium (Ca) and at least one selected from magnesium (Mg), strontium (Sr), and barium (Ba), and y is larger than 0 but does not exceed 0.5 (0<y?0.5).

Abstract: The present invention provides a radiation detector with high detection sensitivity. The radiation detector according to the present invention includes an Al2O3 substrate, a Fe2O3 thin film layered on the Al2O3 substrate, a CaxCoO2 (where 0.15<×<0.55) thin film that is layered on the Fe2O3 thin film and that has CoO2 planes that are aligned inclined to the surface of the Al2O3 substrate, a first electrode disposed on the CaxCoO2 thin film, and a second electrode disposed on the CaxCoO2 thin film in a position opposed to the first electrode in the direction in which the CoO2 planes are aligned inclined.