Abstract: A thermistor that includes: a base layer containing a resin component; a thermistor layer on the base layer, wherein the thermistor layer is a composite which includes a plurality of particles including a metal oxide containing at least one first metal element that is at least one of Mn and Ni, and an amorphous phase between the plurality of particles and which contains the same metal element as the first metal element; two electrodes, wherein the two electrodes include at least one second metal element selected from the group consisting of Cu, Al, Ag, and Ni; and a bonding layer between the two electrodes and the thermistor layer, the bonding layer comprising the composite, the second metal element, and the resin component.

Abstract: A method for manufacturing a sintered body, the method including heating a mixture that contains a plurality of particles of a metal oxide having a spinel-type structure, and a metal acetylacetonate under pressure at a temperature of from a melting point or higher of the metal acetylacetonate to 600° C. or lower, to form a sintered body that contains the metal oxide having the spinel-type structure.

Abstract: A composite that includes multiple first metal oxide particles containing at least one metal element that is at least one of Mn or Ni, and a first amorphous phase between the multiple first metal oxide particles and which contains the at least one first metal element.

Abstract: A laminated thermoelectric conversion element is a laminated thermoelectric conversion element that has: a first end surface and a second end surface opposed to each other; a heat absorption surface; and a heat release surface, where p-type thermoelectric conversion material layers and n-type thermoelectric conversion material layers are electrically connected and at the same time, laminated alternately in a meander form with insulating layers partially interposed there between, in an intermediate part, the p-type thermoelectric conversion material layers are laminated which have a p-type basic thickness, whereas the n-type thermoelectric conversion material layers are laminated which have an n-type basic thickness, and the thickness of the p-type thermoelectric conversion material layer or n-type thermoelectric conversion material layer outside the insulating layer located closest to any of the first end surface and second end surface is larger as compared with the basic thickness of the thermoelectric conve

Abstract: A method for manufacturing a sintered body, the method including heating a mixture that contains a plurality of particles of a metal oxide having a spinel-type structure, and a metal acetylacetonate under pressure at a temperature of from a melting point or higher of the metal acetylacetonate to 600° C. or lower, to form a sintered body that contains the metal oxide having the spinel-type structure.

Abstract: A method for manufacturing a sintered body, the method including heating a mixture that contains a plurality of particles of a metal oxide having a spinel-type structure, and a metal acetylacetonate under pressure at a temperature of from a melting point or higher of the metal acetylacetonate to 600° C. or lower, to form a sintered body that contains the metal oxide having the spinel-type structure.

Abstract: A thermoelectric conversion element that includes a laminate having a p-type semiconductor layer, an n-type semiconductor layer, and an insulating layer. The n-type semiconductor layer forms a pn-junction with a region of the p-type semiconductor layer. The insulating layer is provided in a region where the pn-junction is not formed between the p-type semiconductor layer and the n-type semiconductor layer. The laminate also contains 0.005% by weight to 0.009% by weight of carbon.

Abstract: A temperature detecting device (101) includes: a detecting unit (11) which detects a temperature of a heat source (1); a power generation unit (12) which includes a thermoelectric conversion element (3) and is spaced from the detecting unit (11); a first heat transfer unit (41) that transfers heat or cold of the heat source (1) to the power generation unit (12); a radiator (13) which is remote from the power generation unit (12) so as to radiate heat or cold to outside; a second heat transfer unit (42) that receives heat or cold from the power generation unit (12) and that transfers the heat or cold to the radiating unit (13); and an output unit (14) that outputs a result of the measurement made by the temperature receiving element (2). The thermoelectric conversion element (3) generates electric power by way of a temperature difference between a surface (3a) and a surface (3b) and supplies electric power to the temperature receiving element (2) and the output unit (14).

Abstract: An n-type thermoelectric conversion material that has a high Seebeck coefficient, a low electric resistivity, and a large power factor includes, as its main constituent, a metal material mainly containing Ni, and includes an oxide material containing Sr, Ti, and a rare-earth element in the range of about 10 wt % to about 30 wt %. The oxide material is a SrTiO3 based oxide material. For producing the thermoelectric conversion material, through the steps of mixing and grinding a SrTiO3 based oxide material and a Ni metal powder to prepare a mixture, forming this mixture into a shape to prepare a compact, and then firing the compact, the thermoelectric conversion material is obtained.

Abstract: A laminated thermoelectric conversion element is a laminated thermoelectric conversion element that has: a first end surface and a second end surface opposed to each other; a heat absorption surface; and a heat release surface, where p-type thermoelectric conversion material layers and n-type thermoelectric conversion material layers are electrically connected and at the same time, laminated alternately in a meander form with insulating layers partially interposed there between, in an intermediate part, the p-type thermoelectric conversion material layers are laminated which have a p-type basic thickness, whereas the n-type thermoelectric conversion material layers are laminated which have an n-type basic thickness, and the thickness of the p-type thermoelectric conversion material layer or n-type thermoelectric conversion material layer outside the insulating layer located closest to any of the first end surface and second end surface is larger as compared with the basic thickness of the thermoelectric conve

Abstract: A laminated thermoelectric conversion element is configured to generate electricity from a difference in temperature with respect to a heat-transfer direction. The thermoelectric conversion element includes opposed first and second surfaces which extend in the heat-transfer direction. Respective external electrodes are provided on the first and second surfaces for outputting electricity generated from the temperature difference. At least one of the first and second surfaces is provided with a mark which makes it possible to visually determine the location of the high-temperature side and the low-temperature side with respect to the heat-transfer direction as well as the polarity of the electricity generated.

Abstract: A temperature detecting device (101) includes: a detecting unit (11) which detects a temperature of a heat source (1); a power generation unit (12) which includes a thermoelectric conversion element (3) and is spaced from the detecting unit (11); a first heat transfer unit (41) that transfers heat or cold of the heat source (1) to the power generation unit (12); a radiator (13) which is remote from the power generation unit (12) so as to radiate heat or cold to outside; a second heat transfer unit (42) that receives heat or cold from the power generation unit (12) and that transfers the heat or cold to the radiating unit (13); and an output unit (14) that outputs a result of the measurement made by the temperature receiving element (2). The thermoelectric conversion element (3) generates electric power by way of a temperature difference between a surface (3a) and a surface (3b) and supplies electric power to the temperature receiving element (2) and the output unit (14).

Abstract: A thermoelectric conversion element includes a p-type metal thermoelectric conversion material containing a metal as its main constituent, an n-type oxide thermoelectric conversion material containing an oxide as its main constituent, and a composite oxide insulating material containing a composite oxide as its main constituent. The p-type metal thermoelectric conversion material and the n-type oxide thermoelectric conversion material are directly bonded in a region of a junction plane between the p-type metal thermoelectric conversion material and the n-type oxide thermoelectric conversion material, and the p-type metal thermoelectric conversion material and the n-type oxide thermoelectric conversion material are bonded to each other with the composite oxide insulating material interposed therebetween so as to define a pn conjunction pair in the other region of the junction plane. A perovskite-type oxide is used as the n-type oxide thermoelectric conversion material.

Abstract: An n-type thermoelectric conversion material that has a high Seebeck coefficient, a low electric resistivity, and a large power factor includes, as its main constituent, a metal material mainly containing Ni, and includes an oxide material containing Sr, Ti, and a rare-earth element in the range of about 10 wt % to about 30 wt %. The oxide material is a SrTiO3 based oxide material. For producing the thermoelectric conversion material, through the steps of mixing and grinding a SrTiO3 based oxide material and a Ni metal powder to prepare a mixture, forming this mixture into a shape to prepare a compact, and then firing the compact, the thermoelectric conversion material is obtained.