Patent application number | Description | Published |
20100176822 | NANOWIRE SENSOR - An analyte sensing device is disclosed. In one aspect, the device includes at least one sensing module on a substrate. The sensing module has at least one nanowire including a bottom, an intermediate part and a top, the bottom being closer to the substrate than the top. The module has a surrounding electrode surrounding the bottom and at least part of the intermediate part of each nanowire in height direction and being electrically isolated from the nanowire. There is a gap between each nanowire and the corresponding surrounding electrode allowing penetration of an analyte to be detected between the nanowire and the surrounding electrode. A measurement circuitry is electrically connected to each nanowire and the surrounding electrode for detecting a change in an electrical property as a result of the penetration of the analyte into the gap. | 07-15-2010 |
20100264333 | Gas Sensing Device - The present invention relates to a gas sensing device comprising a nanoparticle layer ( | 10-21-2010 |
20110192720 | MICROFABRICATED LIQUID-JUNCTION REFERENCE ELECTRODE - Micromachined reference electrodes for use in miniaturized electrochemical sensors, and methods for fabricating such reference electrodes and electrochemical sensors, for example, as a part of a microfluidic system, are disclosed. Electrochemical measurements allow for inexpensive detection of a wide variety of (bio-)chemical compounds in solution. The reference electrode is one of the main parts of an electrochemical cell. The reference electrode, from which no current is drawn, has a stable, constant potential. | 08-11-2011 |
20110205543 | Gas Sensor, Method for Optically Measuring the Presence of a Gas Using the Gas Sensor, and Gas Sensing System - The present disclosure relates to a gas sensor including a first layer and a second layer superimposed on each other along an interface between the two layers. The first layer includes an array of nanoparticles along the interface, the nanoparticles provided so as to allow, upon illumination with electromagnetic radiation, long range diffractive coupling of surface plasmon resonances resulting in a surface lattice resonance condition. The second layer includes a material that, when exposed to at least one predetermined gas, detectably affects the surface lattice resonance condition. The material of the second layer preferably has a porosity of at least 10%. | 08-25-2011 |
20120075634 | Sensor, Method for Detecting The Presence and/or Concentration of an Analyte Using the Sensor, and Use of the Method - Methods and sensors for detecting the presence and/or concentration of an analyte are disclosed. In one aspect, a sensing element for use in a sensor is disclosed. The sensing element comprises a resonant cavity device configured to emit optical radiation at an initial power level, a sensing layer exhibiting an initial refractive index, and a detector. The sensing layer is configured to absorb or adsorb an analyte and, in response to absorbing or adsorbing the analyte, exhibit a modified refractive index that differs from the initial refractive index. The resonant cavity device is further configured to, in response to the sensing layer absorbing or adsorbing the analyte, emit optical radiation at a modified power level based on the modified refractive index. The detector is configured to detect the modified power level. | 03-29-2012 |
20120077019 | HUMIDITY BARRIER - A humidity barrier comprises a mixed matrix membrane, wherein the mixed matrix membrane comprises a polymer matrix with at least a hydrophobic surface, in which polymer matrix porous hydrophilic filler particles are dispersed. The hydrophobic surface may be formed either by hydrophobic polymer material itself or a hydrophobic coating may be provided on top of non-hydrophobic polymer material. | 03-29-2012 |
20120151997 | METHOD OF MAKING AN ELECTRICALLY CONDUCTIVE STRUCTURE, METHOD OF MAKING A GAS SENSOR, GAS SENSOR OBTAINED WITH THE METHOD AND USE OF THE GAS SENSOR FOR SENSING A GAS - A method of making an electrically conductive structure in a surface portion of a dielectric material is disclosed. In one aspect, the method includes creating vacancies at at least part of an exposed surface of the dielectric material by removing atoms from a plurality of molecules of the dielectric material. | 06-21-2012 |
20120181185 | CONFIGURATION, A SENSING ELEMENT WITH SUCH CONFIGURATION, ELECTROCHEMICAL SENSOR COMPRISING SUCH SENSING ELEMENT AND METHOD FOR ELECTROCHEMICAL SENSING USING SUCH ELECTROCHEMICAL SENSOR - A configuration is disclosed. In one aspect, the configuration includes a substantially planar electrode layer, in a first plane. The configuration further includes a substantially planar two-dimensional electron gas (2DEG) layer electrically connected in series with the electrode layer. The 2DEG layer is provided in a second plane substantially parallel with the first plane and located at a predetermined distance, in a direction orthogonal to the first plane, from the first plane. The 2DEG layer and the electrode layer are patterned such that the electrode layer overlays a part of the 2DEG layer, wherein the predetermined distance between the first plane and the second plane is selected to be sufficiently small for allowing electrostatic interaction between the electrode layer and the 2DEG layer. | 07-19-2012 |
20120247978 | ELECTROCHEMICAL ETHYLENE SENSOR AND METHOD FOR MONITORING ETHYLENE - An electrochemical ethylene sensor and method for ethylene sensing are disclosed. In one aspect, an electrochemical ethylene sensor includes a working electrode and a counter electrode on an electrically insulating substrate. An ionic liquid layer covers the working electrode and counter electrode. In one method, a voltage is applied to the working electrode which is equal to or lower than the voltage required for the onset of oxidation of the material of the working electrode, for example, in the range spanning 700 mV before the onset of oxidation of the material of the working electrode. | 10-04-2012 |
20130111977 | Chemical Sensor - The application describes methods and apparatus for chemical sensing, e.g. gas sensing, which have high sensitivity but low power operation. A sensor is described having a flexible membrane comprising a III/N heterojunction structure configured so as to form a two dimensional electron gas within said structure. A sensing material is disposed on at least part of the flexible membrane, the sensing material being sensitive to one or more target chemicals so as to undergo a change in physical properties in the presence of said one or more target chemicals. The sensing material is coupled to said heterojunction structure such that said change in physical properties of the sensing material imparts a change in stress within the heterojunction structure which modulates the resistivity of the two dimensional electron gas. | 05-09-2013 |
20130334061 | SENSOR FOR SENSING THE PRESENCE OF AT LEAST ONE FLUIDUM - A Sensor for sensing the presence of at least one fluidum in a space adjoining the sensor is disclosed. In one aspect, the sensor has a two-dimensional electron gas (2DEG) layer stack, a gate electrode overlaying at least part of the 2DEG layer stack for electrostatically controlling electron density of a 2DEG in the 2DEG layer stack and a source and a drain electrode contacting the 2DEG layer stack for electrically contacting the 2DEG, wherein a detection opening is provided in between the gate electrode and the 2DEG layer stack and wherein the detection opening communicates with the space through a detection opening inlet such that molecules of the fluidum can move from the adjoining space through the detection opening inlet into the detection opening where they can measurably alter a electric characteristic of the 2DEG. | 12-19-2013 |
20140012114 | Monitoring of Fluid Content - This application describes methods and apparatus for monitoring of fluid content that are suitable for in-situ, real time and/or continuous monitoring, especially of bodily fluids and in particular the content of sweat. The application also describes fabrication of such an apparatus. The apparatus comprises a multilayer structure comprising at least two electrode layers for detection of fluid content separated by at least one insulating layer. The multilayer structure defines at least one flow channel which provides a flow path for continuous flow of fluid in use, and the electrode layers form part of the sidewall of the flow channel(s). The flow channel(s) may run in a direction substantially perpendicular to the layers. The electrode layers may employ electrochemical detection and may comprise a reference electrode and an ion-sensitive electrode. The apparatus may be fabricated using various printing or deposition techniques. | 01-09-2014 |
20140175516 | TWO-DIMENSIONAL ELECTRON GAS SENSOR AND METHODS FOR MAKING AND USING THE SENSOR - The disclosed technology generally relates to a sensor and methods for making and using the same, and more particularly relates to a sensor configured to sense the presence of at least one fluidum. In one aspect, a sensor for sensing a fluidum in a space adjoining the sensor comprises a two-dimensional electron gas (2DEG) layer stack. The sensor additionally comprises a gate lying adjacent to at least part of the 2DEG layer stack and configured to electrostatically control the electron density of a two-dimensional electron gas (2DEG) in the 2DEG layer stack. The sensor further comprises a source electrode contacting the 2DEG layer stack for electrically contacting the 2DEG. The 2DEG layer stack of the sensor comprises a contact surface contacting the space and provided to contact molecules of the fluidum which is desired to be detected, and the gate of the sensor comprises a doped semiconductor bottom layer of the 2DEG layer stack in electrical contact with at least one gate electrode, where the doped semiconductor bottom layer being located at a side of the 2DEG layer stack opposing the contact surface. | 06-26-2014 |