Patent application number | Description | Published |
20100065895 | Method for producing at least one porous layer - A method for producing at least one porous layer on a substrate, whereby a suspension, which contains particles from a layer-forming material or molecular precursors of the layer-forming material, as well as at least one organic component, is applied to the substrate, the precursors of the layer-forming material are subsequently reacted to produce the layer-forming material following application to the substrate, in a next step, the particles from the layer-forming material are sintered, and the at least one organic component is subsequently removed. Also, a field-effect transistor having at least one gate electrode, the gate electrode having an electrically conductive, porous coating which was applied in accordance with the method. | 03-18-2010 |
20100072621 | ELECTRONIC COMPONENT - An electronic component has a metallic layer on a substrate made of a semiconductor material, a diffusion barrier layer that is made of a material that has a small diffusion coefficient for the metal of the metallic layer being formed between the metallic layer and the substrate. | 03-25-2010 |
20100090255 | Electronic component - An electronic component includes at least one electrode and at least one gas-sensitive region on a substrate. The gas-sensitive region is coated by at least one electrically conductive, gas-sensitive layer, and the electrode contacts the gas-sensitive layer. At least a part of the at least one electrode covers a part of the gas-sensitive region. | 04-15-2010 |
20100133591 | METHOD FOR PASSIVATING A FIELD-EFFECT TRANSISTOR - The present invention relates to a method for passivating a semiconductor component having at least one chemosensitive electrode that is blinded by the application of a glass layer. The present invention also relates to a device for detecting at least one substance included in a fluid stream, including at least one semiconductor component acting as a measuring sensor as well as at least one semiconductor component acting as a reference element, the semiconductor components each having a chemosensitive electrode, and the chemosensitive electrode of the semiconductor component acting as the reference element being passivated. For the passivation, a glass layer may be applied at least to the chemosensitive electrode of the semiconductor component acting as reference element. | 06-03-2010 |
20100139365 | FIELD EFFECT TRANSISTOR GAS SENSOR HAVING A HOUSING AND POROUS CATALYTIC MATERIAL CONTAINAED THEREIN - A gas sensor for determining gas components in gas mixtures, e.g., for exhaust gases of internal combustion engines, includes a housing and a sensor element configured as a field effect transistor which has source, drain, and gate electrodes applied on a semiconductor substrate. A porous, catalytically active material is provided inside the housing of the gas sensor. | 06-10-2010 |
20100193375 | SEMICONDUCTOR GAS SENSOR HAVING ADDITIONAL FUNCTIONALITIES OF THE SIGNAL-GENERATING ELECTRODE - In a method for operating a semiconductor gas sensor, the gas sensor including at least one gas-sensitive electrode, the method may provide for impression of a voltage sequence on the gas-sensitive electrode. The operation may take place in a measuring cycle which is subdivided into at least one initialization phase and at least one subsequent measuring phase, a first voltage sequence being impressed on the gas-sensitive electrode during the initialization phase, a second voltage sequence being impressed on the gas-sensitive electrode during the measuring phase, and the first voltage sequence differing from the second voltage sequence. A semiconductor gas sensor may be provided for implementing the method according to the invention, and a method may relate to the use of such a sensor. | 08-05-2010 |
20110132773 | APPARATUS AND METHOD FOR DETECTING SUBSTANCES - An apparatus for detecting at least one substance present in a fluid flow includes at least one field effect transistor which acts as a measuring sensor, and at least one field effect transistor which acts as a reference element, the field effect transistors each having at least one source electrode, one drain electrode, and one gate electrode. The gate electrode of the field effect transistor which acts as the measuring sensor is sensitive to the at least one substance to be detected, and the gate electrode of the field effect transistor which acts as the reference element is essentially insensitive to the at least one substance to be detected. The source electrode of one of the field effect transistors and the drain electrode of the other of the field effect transistors are connected to one another and to a signal line. A method for detecting at least one substance present in a fluid flow by using the apparatus is also described, a potential of 0 volt being applied to the signal line and the current flowing on the signal line being measured. | 06-09-2011 |
20110193140 | Electronic component for high temperatures - A chemically sensitive field effect transistor includes a substrate, a conductor track structure situated on the substrate, and a functional layer which is contacted via the conductor track structure. To be able to form a thin, oxidation-stable and temperature-stable conductor track structure, the conductor track structure is made of a metal mixture which includes platinum and one or more metals selected from the group made up of rhodium, iridium, ruthenium, palladium, osmium, gold, scandium, yttrium, lanthanum, the lanthanides, titanium, zirconium, hafnium, niobium, tantalum, chromium, tungsten, rhenium, iron, cobalt, nickel, copper, boron, aluminum, gallium, indium, silicon, and germanium. | 08-11-2011 |
20110266681 | ELECTRONIC COMPONENT AS WELL AS METHOD FOR ITS PRODUCTION - An electronic component includes at least one patterned layer of an electrically conductive material on a substrate, a protective layer of a second material being deposited on the patterned layer of the electrically conductive material. The second material is baser than the electrically conductive material of the patterned layer. In a method for producing the electronic component, the patterned layer of the electrically conductive material is deposited on the substrate in a first step, and the protective layer of the second material, which is baser than the electrically conductive material of the patterned layer, is deposited on the patterned layer in a second step. | 11-03-2011 |
20110272747 | Electronic component - An electronic component includes a printed conductor structure on a substrate, as well as a film which contacts the printed conductor structure. The film has a smaller layer thickness than the printed conductor. The printed conductor structure has a region which is covered by the film for the purpose of contacting. | 11-10-2011 |
20130045541 | OPTICAL GAS SENSOR - A gas sensor and method for ascertaining the concentration of one or more gas species, in the exhaust gas of an internal combustion engine. The gas sensor includes a measuring cell having a gas inlet, a gas outlet, a catalysis area, and an analysis area. The sensor also includes a catalytic converter for catalyzing a reaction of a first gas species to form a second gas species in the catalysis area, and a gas analyzer for spectroscopically measuring the concentration of the second gas species in the analysis area. Through the catalytic converter, a first gas species may be converted into a second gas species whose absorption and/or scattering wavelength(s) are within the emission wavelength range of semiconductor radiation sources, so that the gas analyzer may have a semiconductor radiation source. | 02-21-2013 |
20130192989 | MICROMECHANICAL SOLID-ELECTROLYTE SENSOR DEVICE AND CORRESPONDING PRODUCTION METHOD - A micromechanical solid-electrolyte sensor device includes a micromechanical carrier substrate having a front side and a back side. The micromechanical solid-electrolyte sensor device also includes a first porous electrode and a second porous electrode. The micromechanical solid-electrolyte sensor device also includes a solid-electrolyte embedded between the first porous electrode and the second porous electrode. | 08-01-2013 |
20140261348 | Exhaust Gas Sensor Device - An exhaust gas sensor device for recording a concentration of at least one exhaust gas component in an exhaust system of an internal combustion engine includes at least one exhaust gas sensor with intrinsic signal amplification. The at least one exhaust gas sensor records the concentration of at least one exhaust gas component. | 09-18-2014 |
20140262827 | Microelectrochemical Sensor and Method for Operating a Microelectrochemical Sensor - A microelectrochemical sensor includes an energy supply unit and a sensor unit. The energy supply unit is configured to generate electrical energy using a reference fluid. The sensor unit is configured to determine a concentration difference of a chemical species between a measuring fluid and the reference fluid. The measuring fluid has an unknown concentration of the species, and the reference fluid has a known concentration of the species. The sensor unit is electrically connected to the energy supply unit and is designed to determine the concentration difference using the electrical energy from the energy supply unit. | 09-18-2014 |
20140262834 | Microelectrochemical Sensor and Method for Operating a Microelectrochemical Sensor - A microelectrochemical sensor includes a carrier material composed of a semiconductor substrate, and includes a chemosensitive sensor element. The chemosensitive sensor element is positioned in a first partial region of the carrier material. A heating element is positioned in a region of the chemosensitive sensor element and is configured to regulate a temperature of the chemosensitive sensor element. A microelectronic unit is positioned in a second partial region of the carrier material, and is connected to the chemosensitive sensor element and the heating element via conductor tracks integrated into the carrier material. The microelectronic unit is configured to operate the heating element and the sensor element. | 09-18-2014 |
20140262838 | Microelectrochemical Sensor and Method for Operating a Microelectrochemical Sensor - A microelectrochemical sensor having a diaphragm, a web, a first and a second electrode. The diaphragm is permeable to ions of a chemical species, is arranged transversely with respect to a cutout in a base body, and closes off the cutout in a fluid-tight fashion. The web is arranged on a first side of the diaphragm between a first partial surface and a second partial surface, and is designed to adjust a temperature of the diaphragm to an operating temperature using electrical energy. The first electrode has a first partial electrode and a second partial electrode, is permeable to fluid, and is arranged on the first side of the diaphragm. The web prevents electrical contact between the first electrode and the diaphragm. The second electrode has a third partial electrode and a fourth partial electrode, is also permeable to fluid, and is arranged on a second side of the diaphragm. | 09-18-2014 |
20140273258 | Functional Element for Arranging in Front of the Active Measuring Region of a Sensor Element - A functional element positioned in front of an active detection region of a sensor element has a compact main body with a gas-side surface, a sensor-side surface, and at least two functional channels located between the gas-side surface and the sensor-side surface. The functional channels have a functionality that is different from one another with respect to a gas that can pass through. Such a functional element allows particularly variable operation of a sensor with great long-term stability. | 09-18-2014 |
20140283581 | Sensor Device for Sensing a Gas, Method for Operating a Sensor Device for Sensing a Gas and Production Method for a Sensor Device for Sensing a Gas - A sensor device for sensing a gas includes a sensing region, and a readout region that is electrically and mechanically connected to the sensing region by way of a connecting web. The readout region, the sensing region, and the connecting web are formed from a substrate, and are isolated from the substrate by a clearance cutout. The sensing region has an ion-conducting region configured to provide a measuring signal dependent on the gas. The readout region (is configured to read out the measuring signal. | 09-25-2014 |
20140283632 | Sensor Device and Method for Producing a Sensor Device - A sensor device includes a sensor element configured to detect a measurement value based at least in part upon a physical variable, and a support element configured to support the sensor element. The support element has at least one connection region which is located in a section of the support element, and which is configured to connect the section of the support element to a section of the sensor element such that the sensor element is mounted so as to be movable with respect to the support element. | 09-25-2014 |
20140305812 | METHOD FOR ANALYZING A GAS - A method for analyzing a gas includes measuring a concentration of a chemical species of the gas in a measuring space of a gas sensor. The gas sensor has a semiconductor substrate with an electrical circuit and a first thin-film ion conductor that separates a reference space for a reference gas from the measuring space for the gas. The first thin-film ion conductor has a reference electrode that faces the reference space and a measuring electrode that faces the measuring space. The reference electrode and the measuring electrode are connected to the electrical circuit. The measuring of the chemical species includes picking off an electrical voltage between the reference electrode and the measuring electrode of the gas sensor. A partial pressure of the chemical species in the gas is determined by processing the electrical voltage in the electrical circuit by using a stored processing specification. | 10-16-2014 |
20140374778 | Optical Assembly - An optical assembly configured to emit electromagnetic radiation comprises first and second electroluminescent semiconductor components positioned adjacent to each other. The first electroluminescent semiconductor component is transparent to electromagnetic radiation generated by the second electroluminescent semiconductor component, and the second electroluminescent semiconductor component is transparent to electromagnetic radiation generated by the first electroluminescent semiconductor component. The first electroluminescent semiconductor component and the second electroluminescent semiconductor component are configured to actuate independently of each other. | 12-25-2014 |