A thermoelectric conversion element is made of a material with a band structure having Weyl points in the vicinity of Fermi energy. The thermoelectric conversion element has a thermoelectric mechanism for generating electromotive force by the anomalous Nernst effect. A thermoelectric conversion device includes a substrate; and a power generator provided on the substrate and including a plurality of thermoelectric conversion elements. Each of the plurality of thermoelectric conversion elements has a shape extending in one direction, and is made of a material identical to that of the above-mentioned thermoelectric conversion element. The plurality of thermoelectric conversion elements is arranged in parallel to one another in a direction perpendicular to the one direction and electrically connected in series to one another in a serpentine shape.

We disclose a chemical sensing device for detecting a fluid. The sensing device comprises: at least one substrate region comprising at least one etched portion; a dielectric region formed on the at least one substrate region, the dielectric region comprising at least one dielectric membrane region adjacent to the at least one etched portion; an optical source for emitting an infra-red (IR) signal; an optical detector for detecting the IR signal emitted from the optical source; one or more further substrates formed on or under the dielectric region, said one or more further substrates defining an optical path for the IR signal to propagate from the optical source to the optical detector. At least one of the optical source and optical detector is formed in or on the dielectric membrane region.

A device for detecting electromagnetic radiation is provided, including a substrate; at least one thermal detector placed on the substrate; and an encapsulating structure encapsulating the detector, including a thin encapsulating layer of a material that is transparent to said radiation, extending around and above the detector so as to define with the substrate a cavity in which the detector is located; wherein the thin encapsulating layer comprises a peripheral wall that encircles the detector, and that has a cross section, in a plane parallel to the plane of the substrate, of square or rectangular shape, corners of which are rounded.

A thermoelectric conversion device (20) includes a substrate (22) and a plurality of thermoelectric conversion elements (24, 25) on the substrate (22) . Each of the plurality of thermoelectric conversion elements (24, 25) has a rectangular parallelepiped shape and is made of an alloy including Fe.sub.3Sn.sub.2, an iron nitride (such as Fe.sub.16N.sub.2), or a rare-earth element and Co, the alloy exhibiting an anomalous Nernst effect. The thermoelectric conversion elements (24, 25) are arranged parallel to a direction (y direction) perpendicular to a longitudinal direction (x direction) to form a serpentine shape, and electrically connected in series.

A cooling system includes a plurality of sensor sub-units arranged in a grid having first sides configured to be thermally connected to a heat source and opposing second sides. The heat source including a plurality of sub-regions that correspond with the first sides of each of the plurality of sensor sub-units. The plurality of sensor sub-units are configured to sample temperatures of the sub-regions of the heat source. The cooling system also includes a plurality of solid-state cooling sub-units configured to dissipate heat, a plurality of heat exchanger channels and a controller configured to determine the one or more sub-regions of the heat source to cool. Each heat exchanger channel is configured to dissipate heat. At least one surface of at least one of the heat exchanger channels includes a coating configured to boost conversion of heat energy being dissipated into infrared radiation.

Methods, apparatuses, and systems associated with tunable pumped two-phase liquid cooling thermal management are disclosed. In embodiments, a tunable cooling apparatus may include a thermoelectric cooler device, TEC, that has a hot side and a cold side, where the cold side is to cool the coolant in route to an inlet manifold of the cold plate before the coolant enters the inlet manifold, and the hot side may be to warm the coolant in route from an outlet manifold of the cold plate after the coolant flows through the cold plate and exits the outlet manifold and or vice versa. In embodiments, the coolant may be either in a liquid state or in a vapor state. Other embodiments may be described and/or claimed.

A thermoelectric conversion element includes a substrate, a thermoelectric conversion layer disposed on a first main surface of the substrate, an insulating layer covering the thermoelectric conversion layer, a first electrode disposed on the insulating layer and connecting to a first main surface of the thermoelectric conversion layer via a first contact hole of insulating layer, and a second electrode disposed on the insulating layer and connecting to the first main surface of the thermoelectric conversion layer via a second contact hole of the insulating layer. At least a portion of the first electrode is formed from a material that has a work function that is different from a work function of a material forming the second electrode.

A thermoelectric generation module having: a base material; a plurality of electrodes disposed on the base material; and a thermoelectric conversion layer that coats each of the electrodes individually leaving a portion of the electrode to which a wiring is to be connected, wherein the thermoelectric conversion layer adheres to the base material around the electrode excluding the portion of the electrode to which the wiring is to be connected.

A thermoelectric conversion element that has a power generation layer containing an iron-aluminum based magnetic alloy material containing equal to or more than 70 weight percent of iron and aluminum in total. The power generation layer generates an electromotive force, due to an anomalous Nernst effect that develops in the magnetic alloy material in response to a temperature gradient applied thereto, in a direction intersecting both the magnetization direction of the magnetic alloy material and the direction of the applied temperature gradient.

A thermal stabilization system stabilizes inertial measurement unit (IMU) performance by reducing or slowing operating variations over time of the internal temperature. More specifically, a thermoelectric heating/cooling device operates according to the Peltier effect, and uses thermal insulation and a mechanical assembly to thermally and mechanically couple the IMU to the thermoelectric device. The thermal stabilization system may minimize stress on the IMU and use a control system to stabilize internal IMU temperatures by judiciously and bidirectionally powering the thermoelectric heating/cooling device. The thermal stabilization system also may use compensation algorithms to reduce or counter residual IMU output errors from a variety of causes such as thermal gradients and imperfect colocation of the IMU temperature sensor with inertial sensors.