Abstract: In an embodiment A package includes a casing having an opening and enclosing a cavity, a die accommodated in the cavity and a membrane attached to the casing, the membrane being air-permeable, covering and sealing the opening, wherein the membrane is configured to allow only a lateral gas flow, and wherein a blocking member is configured to block a vertical gas flow through the membrane into the cavity, the blocking member tightly covering a surface of the membrane at least in an area comprising the opening.

Abstract: In an embodiment a method includes providing a substrate with an electrical functional layer comprising a plurality of functional regions, wherein the functional regions are electrically addressable independently from each other, wherein the plurality of functional regions comprises at least a first group of functional regions and a second group of functional regions, wherein the first group is different from the second group, and wherein at least one functional region is part of the first group and of the second group and performing a multiple-mask process by applying a first mask on the electrical functional layer, wherein the first mask exposes the functional regions of the first group and covers all other functional regions, applying a first sensor material over the exposed functional regions by sputtering, removing the first mask, applying a second mask on the electrical functional layer, wherein the second mask exposes the functional regions of the second group and covers all other functional regions, a

Abstract: In an embodiment a sensor device includes a substrate with a first membrane and a first cover layer, the first membrane and the first cover layer being monolithically integrated into the substrate and a first pellistor element including a heater element and a temperature sensor element, the heater element and/or the temperature sensor element being arranged in or on the first membrane, wherein the first cover layer is arranged over or under the first membrane, and wherein the first membrane, the first cover layer and a part of the substrate surround a first cavity.

Abstract: The present invention relates to a method allowing a particularly efficient ligand exchange of a detergent bilayer on the surface of metal nanoparticles for molecular functionalization and assembly, and corresponding functionalized nanoparticles and nanoparticle assemblies that can be prepared using this method, as illustrated in FIG. 16, as well as their use, e.g., for plasmonic applications such as surface-enhanced Raman scattering (SERS). In particular, the invention provides corresponding methods for preparing a dimeric nanoparticle assembly, a core-satellite nanoparticle assembly, and a functionalized nanoparticle, respectively.

Abstract: In an embodiment an electrochemical gas sensor includes a base plate comprising a base plate main surface, a catalytic layer configured to enhance chemical reactivity of gases, the catalytic layer is arranged on top of the base plate main surface and a solid electrolyte layer arranged on top of the catalytic layer, wherein the solid electrolyte layer comprises a ceramic material, and wherein the catalytic layer and the solid electrolyte layer are electrically contacted by contacts.

Abstract: A gas sensor with improved sensitivity. The gas sensor comprises an active sensor unit, a reference sensor unit and a temperature control circuit. The active sensor unit has an active detector. The reference sensor unit has a reference detector. The temperature control circuit is provided and configured to keep a detector at a predetermined temperature.

Abstract: A method for testing a gas sensor and a gas sensor are disclosed. In an embodiment a method for testing at least one gas sensor includes exposing in a first measurement the gas sensor to a test gas under first gas conditions including a first pressure and exposing in a second measurement the gas sensor to the test gas under second gas conditions including a second pressure, the second gas conditions being different from the first gas conditions, wherein the second pressure is different from the first pressure, and/or wherein the gas sensor is exposed to an intermediate pressure different from the first pressure between the first measurement and the second measurement.

Abstract: A method and apparatus for operating a gas sensor are disclosed. In an embodiment a method for operating a gas sensor includes providing, by at least one gas sensor element, a sensing signal and correcting, by a neural network, the sensing signal, wherein the neural network comprises an input layer, an output layer and at least one hidden layer, wherein the input layer comprises a given number k>1 of input neurons for each gas sensor element, and wherein a respective gas sensor element provides its sensing signal to one of the corresponding input neurons dependent on a measurement parameter applied to the at least one gas sensor element.

Abstract: A sensor component and a mobile communication device including a sensor component are disclosed. In an embodiment a sensor component includes a subcomponent configured to sense a gas level including a resistive heater and a gas sensitive element disposed on the resistive heater; a package enclosing a cavity and accommodating the subcomponent, the package including a first opening in a position facing the gas sensitive element of the subcomponent and a second opening configured to allow a flow of gas to enter the package through the first opening and exit the package through the second opening; and an evaluation circuit configured to generate an output signal indicative of a speed of the flow of gas in response to electrical power to be supplied to the resistive heater.

Abstract: A method and apparatus for operating a multi-gas sensor are disclosed. In an embodiment, a method includes providing at least one calibration input comprising sensor design data of the multi-gas sensor, which varies dependent on production process parameters, and/or sensor production process parameter data of the multi-gas sensor, and/or measurement results of the multi-gas sensor captured when the multi-gas sensor is exposed to one of the gases or a gas mixture to be detected and/or sensed by the multi-gas sensor; providing a trained neural network including an input layer with K input nodes, an output layer with L output nodes and at least one hidden layer; storing each calibration input as a fixed input to a corresponding input node of the trained neural network; and providing a multi-gas sensor output for at least a part of the gases to be detected and/or sensed by the multi-gas sensor dependent on the trained neural network and actual measured sensor values from the sensor elements.

Abstract: A MEMS gas sensor is disclosed. In an embodiment a MEMS gas sensor includes a carrier having a recess, a gas sensitive element arranged in the recess and a shielding layer at least partially covering the recess.

Abstract: A method for operating a sensor device for measuring a concentration of a gas species in a gas is disclosed. In an embodiment, the method includes recording a set of data points by performing a plurality of measurements of a temperature sensor element reading, wherein each of the measurements is performed with a different heater setting of the first pellistor element and each of the measurements results in a data point of the set of data points, performing a curve fit of an evaluation function to the set of data points, wherein the evaluation function comprises a first function and a second function, wherein the first function is based on an ideal behavior of the first pellistor element, and wherein the second function is a temperature-dependent steadily rising or steadily falling function and determining the concentration of the gas species in the gas from the curve fit.

Abstract: A sensor device and an electronic assembly are discloses. In an embodiment a sensor device includes a first pellistor element, a second pellistor element, a heater element, a first temperature sensor element and a second temperature sensor element, wherein the heater element and the first temperature sensor element are part of the first pellistor element and the heater element and the second temperature sensor element are part of the second pellistor element.

Abstract: A sensor device, a method for operating a sensor device and an electronic assembly comprising a sensor device are disclosed. In an embodiment a sensor device includes a first sensor unit and a second sensor unit in a common housing, wherein each of the first and second sensor units comprises a heater element and a temperature sensor element, wherein the housing comprises a cover element having an opening, the cover element covering the first sensor unit, and wherein the opening is arranged over the second sensor unit.

Abstract: A process for the formation of a graphene membrane component includes arranging a graphene membrane in a relaxed condition of the graphene membrane on a surface of a supportive substrate. The graphene membrane extends across a cut-out with an opening at the surface of the supportive substrate. The graphene membrane is moreover arranged so that a first portion of the graphene membrane is arranged on the surface of the supportive substrate and a second portion of the graphene membrane is arranged over the opening of the cut-out. The process further includes tensioning of the second portion of the graphene membrane, in order to convert the second portion of the graphene membrane to a tensioned condition, so that the second portion of the graphene membrane is permanently in the tensioned condition in an operating temperature range of the graphene membrane component.

Abstract: A layer structure may include a carrier, a two-dimensional layer, and a holding structure. The holding structure is arranged on the carrier and holds the two-dimensional layer on the carrier such that at least a portion of the two-dimensional layer is spaced apart from the carrier. The holding structure includes a holding portion extending from the two-dimensional layer towards the carrier beyond the at least a portion of the two-dimensional layer spaced apart from the carrier.

Abstract: A method for testing a plurality of sensor devices, a panel and a sensor component are disclosed. In an embodiment a method includes providing the plurality of sensor devices, each sensor device including a sensor element configured to sense an ambient condition, a heating element to heat the sensor element, connection terminals for a supply voltage and at least one connection terminal for a sense signal indicative of a state of the sensor element, providing a panel including a plurality of groups of connection pads, the connection pads of each one of the groups configured to be connected to the connection terminals of one of the sensor devices, mounting the sensor devices to the groups of connection pads, applying a supply voltage to the sensor devices and concurrently heating the heating elements of the sensor devices to an elevated temperature and calibrating the sensor devices at least one after another.

Abstract: A process for the formation of a graphene membrane component includes arranging a graphene membrane in a relaxed condition of the graphene membrane on a surface of a supportive substrate. The graphene membrane extends across a cut-out with an opening at the surface of the supportive substrate. The graphene membrane is moreover arranged so that a first portion of the graphene membrane is arranged on the surface of the supportive substrate and a second portion of the graphene membrane is arranged over the opening of the cut-out. The process further includes tensioning of the second portion of the graphene membrane, in order to convert the second portion of the graphene membrane to a tensioned condition, so that the second portion of the graphene membrane is permanently in the tensioned condition in an operating temperature range of the graphene membrane component.

Abstract: A process for the formation of a graphene membrane component includes arranging a graphene membrane in a relaxed condition of the graphene membrane on a surface of a supportive substrate. The graphene membrane extends across a cut-out with an opening at the surface of the supportive substrate. The graphene membrane is moreover arranged so that a first portion of the graphene membrane is arranged on the surface of the supportive substrate and a second portion of the graphene membrane is arranged over the opening of the cut-out. The process further includes tensioning of the second portion of the graphene membrane, in order to convert the second portion of the graphene membrane to a tensioned condition, so that the second portion of the graphene membrane is permanently in the tensioned condition in an operating temperature range of the graphene membrane component.

Abstract: A drawer wall element for a drawer. A marginal section of a drawer base is insertable to form a drawer side wall that adjoins the drawer base. The drawer wall element comprises a wall profile part and a base-receiving profile part. The drawer wall element comprises a support surface, present on the base-receiving profile part, for providing underside support to the drawer base. The wall profile part comprises a chamber section having an inner wall sheet section and an outer wall sheet section. A filler element is inserted into the chamber section. The filler element comprises a spring element, which in an inserted state has a defined pretension.