A handheld aerosol-generating device may include an emitter configured to emit light, a sensor configured to receive light, and an aerosol chamber configured to hold an aerosol. The emitter may emit light into the aerosol chamber. The sensor may receive light from the aerosol chamber and measure at least one wavelength of the spectrum of the received light. Direct measurement of parameters, and/or the presence, of the aerosol in the aerosol chamber may be enabled, where the direct measurement of parameters of the aerosol in the aerosol chamber may enable optimal operation of an aerosol-generating system that may be the handheld aerosol-generating device.

An assembly (10) comprising a sample block (12), a heat sink (30) and at least one electrodeposited thermoelectric element (48) is disclosed. Further, an instrument and a method for performing a temperature-dependent reaction are disclosed.

The present disclosure relates to a heating device and a biochemical reactor having the heating device. The heating device includes an upper plate, a lower plate, a middle plate, and an electric heating element. The upper plate has an upper heating hole, an upper receiving hole, and an upper conductive layer. The lower plate has a lower heating hole, a lower receiving hole, and a first lower conductive layer. The middle plate is disposed between the upper and lower plates and has a middle heating hole and a middle receiving hole. The upper, middle and lower receiving holes are connected together to form a receiving through hole. The electric heating element is disposed in the receiving through hole and has two terminals connected to the upper conductive layer and the lower conductive layer, respectively.

An aerosol-generating system may include a device body and a cartridge configured to be removably inserted into or connected to the device body. The device body may include a power supply and an electrical heater connected to the power supply. The cartridge contains an aerosol-forming substrate in the form of a thermoreversible gel that is a solid at room temperature.

A system for the low-temperature remediation of a target volume comprised of at least one material, the system comprising: one or more heaters, wherein the one or more heaters are configured to connect to a power source and emit heat into their surrounding area at substantially uniform rates and the one or more heaters are at least partially embedded into the target area: a power control and monitoring system configured to deliver voltage and current to the one or more heaters at a substantially uniform rate; and a power source configured to deliver voltage and current to the power control and monitoring system for distribution.

A heating apparatus for a gas chromatography column is described. The GC column heating apparatus includes a conical heater assembly comprising a heating element between an inner layer and an outer layer. The apparatus can also include optionally an outer cowl and/or an inner cowl surrounding the conical heater assembly. The conical heater assembly rapidly increases the temperature of the column by conductive heating. The selection of shape (in particular, the cone angle of a conical heater) and materials allows the GC column to adapt to expansion that occurs upon heating. A gas chromatography (GC) column heating and cooling apparatus is also described, in which the heater and outer cowl define a flowpath through which a cooling fluid can pass and cool the GC column.

The invention provides a substrate processing device and a substrate processing method for cooling a substrate, which are capable of conveying a substrate in a cleaner condition. A substrate cooling device serving as a substrate processing device of an embodiment of the invention includes: a chamber; a cooling unit which performs cooling; a substrate holder which is provided with a substrate mounting surface for mounting a substrate inside the chamber, and is cooled by the cooling unit; and a shield which is provided with a side surface portion surrounding a lateral side of the substrate mounting surface inside the chamber, and is cooled by the cooling unit. Moreover, a shield heater is provided in the vicinity of a surface on the inside of the shield.

Electronic devices that include a composition that can generate a gaseous oxidizing agent component; and a generating device configured to actively cause the composition to generate the gaseous oxidizing agent component. The generating device includes at least one metal-air battery that is in electrical communication with a power source that is configured to apply power to the metal-air battery according to a predetermined time interval to recharge the metal-air battery to generate the gaseous oxidizing agent component.

A heater section includes a plate-like ceramic body (a first substrate layer 1, a second substrate layer 2, and a third substrate layer 3) having a longitudinal direction (front-rear direction) and a short-length direction (left-right direction), and a heater 72 disposed within the plate-like ceramic body and including a lead section 79 and a heating section 76 connected to the lead section 79. The heating section 76 includes a straight portion 78 extending along the longitudinal direction, and a lead side curved portion 77b connected to one of the ends of the straight portion 78 closer to the lead section 79. The lead side curved portion 77b has a lower resistance per unit length than the straight portion 78 at one or more temperatures in the range of 700 C. to 900 C.

The heater 72 of the heater portion includes the linear portions 78 and the bend portions 77. A resistance value per unit length of the bend portions 77 at least at a temperature within a temperature range of no less than 700 C. and no more than 900 C. is lower than a resistance value per unit length of the linear portions 78.