An internal temperature measuring apparatus includes a base and a MEMS device disposed on the base. The MEMS device includes a top face and a support. The top face includes a first thermopile configured to measure a first temperature difference used to calculate an internal temperature and a second thermopile configured to measure a second temperature difference used to calculate the internal temperature together with the first temperature difference. An orientation in which a cold junction of each thermocouple constituting the first thermopile is viewed from a hot junction coincides with an orientation in which a cold junction of each thermocouple constituting the second thermopile is viewed from a hot junction.

In one aspect, the present invention relates to a thermocouple device comprising a flexible non-planar substrate, a first printed thermocouple element comprising a first metal containing ink composition applied to the flexible non-planar substrate, and a second printed thermocouple element in electrical contact with the first printed thermocouple element making a thermocouple junction. The second printed thermocouple element comprises a second metal containing ink composition with a Seebeck coefficient sufficiently different from the first metal containing ink composition for the first and second printed thermocouple elements to together produce a thermocouple effect. The present application further relates to medical devices comprising the thermocouple and methods of making such devices.

Provided is an internal temperature measurement device capable of measuring an internal temperature of a measuring object for which the thermal resistance value of a non-heating body present on the surface side of the object is unknown, more accurately with better responsiveness than hitherto. The internal temperature measurement device 10 includes a MEMS chip 12 including: two cells 20a, 20b for measuring two heat fluxes for calculating an internal temperature of a measuring object for which the thermal resistance value of a non-heating body is unknown; and a cell 20c for increasing a difference between the heat fluxes.

A MEMS microphone and a method for manufacturing a MEMS microphone are disclosed. Embodiments of the invention provide a MEMS microphone including a MEMS microphone structure having at least one counter electrode structure and a diaphragm structure deflectable with respect to the counter electrode structure and a thermocouple arranged at the MEMS microphone structure.

The subject of the present invention relates to a device that can be applied to the surface of a ceramic matrix composites (CMC) in such a way that the CMC itself will contribute to the extraordinarily large thermoelectric power. The present invention obtains greater resolution of temperature measurements, which can be obtained at exceedingly high temperatures.

A multi-purpose Micro-Electro-Mechanical Systems (MEMS) thermopile sensor able to use as a thermal conductivity sensor, a Pirani vacuum sensor, a thermal flow sensor and a non-contact infrared temperature sensor, respectively. The sensor comprises a rectangular membrane created in a silicon substrate which has a thin polysilicon layer and a thin residual thermal reorganized porous silicon layer both attached on its back side, and configured to have its three sides clamped to the frame formed in the silicon substrate which surrounds and supports the membrane and the other side free to the frame, a cavity created in the silicon substrate, positioned under the membrane and having its flat bottom opposite to the membrane, its three side walls shaped as curved planes and the other side wall shaped as a vertical plane, a heater or an infrared absorber positioned on the membrane, close to and parallel with the free side of the membrane and a thermopile positioned on the membrane and consists of several thermocouples connected in series and having its hot junctions close to the heater and its cold junctions extended to the frame.

A manufacturing method for a thermoelectric nanosensor includes the following steps. A first conductive material is prepared. A plurality of tellurium nanostructures are formed on the first conductive material. A second conductive material is prepared. The second conductive material is formed on the tellurium nanostructures.

A semiconductor device includes a semiconductor substrate of silicon carbide, and a temperature sensor portion. The semiconductor substrate includes a portion in which an n-type drift region and a p-type body region are laminated. The temperature sensor portion is disposed in the semiconductor substrate and is separated from the drift region by the body region. The temperature sensor portion includes an n-type cathode region being in contact with the body region, and a p-type anode region separated from the body region by the cathode region.

The present invention, in one embodiment, provides a method of measuring pressure or temperature using a sensor including a sensor element composed of a plurality of carbon nanotubes. In one example, the resistance of the plurality of carbon nanotubes is measured in response to the application of temperature or pressure. The changes in resistance are then recorded and correlated to temperature or pressure. In one embodiment, the present invention provides for independent measurement of pressure or temperature using the sensors disclosed herein.

Methods for transferring graphene to substrates include at least a method for transferring a graphene-metal bilayer to a substrate to form a laminate thereof. The method can include applying a first continuous polymer layer to a graphene layer of the graphene-metal bilayer; applying a first discontinuous polymer layer to the first continuous polymer layer; applying a second continuous polymer layer to a metal layer of the graphene-metal bilayer; applying a second discontinuous polymer layer to the second continuous polymer layer; etching the first continuous polymer layer with a first etchant through the first discontinuous polymer layer; laminating the substrate by pressing the face of the graphene layer into a surface of the substrate; etching the second continuous polymer layer with a second etchant through the second discontinuous polymer layer, thereby transferring the graphene-metal bilayer to the substrate to form the laminate.