Abstract: A method for forming a self-cleaning coating, comprises providing a first dispersion comprising plasmonic nanoparticles by suspending plasmonic nanoparticles in an organic medium and providing a second dispersion comprising a precursor of a photocatalytic matrix in an organic medium. The method further comprises forming a mixture of the first and second dispersion and coating the mixture on a surface. The method also comprises calcining the coated mixture.

Abstract: A photocatalytic reactor for use in a heating, ventilation and/or air conditioning system, and comprises a longitudinal housing having a wall and allowing air or gas to pass through along the longitudinal direction of the longitudinal housing. A plurality of tubes are positioned in the longitudinal housing and arranged such that some outer tubes are positioned closer to the housing wall than some inner tubes. The tubes have their longitudinal axis parallel with the longitudinal axis of the longitudinal housing allowing the air or gas to pass along and through the tubes and the tubes comprise photocatalytic material in or on their tube walls. The system comprises an irradiation system for irradiating the photocatalytic material for inducing catalytic action. The irradiation system and plurality of tubes are configured so that upon irradiating by the irradiation system photocatalytic material of the outer tubes and inner tubes is irradiated.

Abstract: A method for forming a self-cleaning coating, comprises providing a first dispersion comprising plasmonic nanoparticles by suspending plasmonic nanoparticles in an organic medium and providing a second dispersion comprising a precursor of a photocatalytic matrix in an organic medium. The method further comprises forming a mixture of the first and second dispersion and coating the mixture on a surface. The method also comprises calcining the coated mixture.

Abstract: A photocatalytic reactor for use in a heating, ventilation and/or air conditioning system, and comprises a longitudinal housing having a wall and allowing air or gas to pass through along the longitudinal direction of the longitudinal housing. A plurality of tubes are positioned in the longitudinal housing and arranged such that some outer tubes are positioned closer to the housing wall than some inner tubes. The tubes have their longitudinal axis parallel with the longitudinal axis of the longitudinal housing allowing the air or gas to pass along and through the tubes and the tubes comprise photocatalytic material in or on their tube walls. The system comprises an irradiation system for irradiating the photocatalytic material for inducing catalytic action. The irradiation system and plurality of tubes are configured so that upon irradiating by the irradiation system photocatalytic material of the outer tubes and inner tubes is irradiated.

Abstract: A gas sensor is provided for measurement of oxygen and/or the air-to-fuel lambda ratio and hydrocarbons and/or carbon monoxide in gas mixtures. To reliably measure a plurality of gaseous components, the sensor is provided with a reference electrode representing a constant oxygen partial pressure, an oxygen ion-conducting solid electrolyte, and at least two measuring electrodes, the measuring electrodes and the reference electrode being mounted directly on the solid electrolyte and having electrical leads for connection and for take-away of electrical measurement signals. The solid electrolyte (1) is constructed with a measurement gas side exposed to the gas mixture and a reference gas side separated from the gas mixture.

Abstract: A method of measuring oxygen and/or the air-to-fuel lambda ratio and hydrocarbons and/or carbon monoxide in gas mixtures using a gas sensor is provided. To reliably measure a plurality of gaseous components, the sensor is provided with a reference electrode representing a constant oxygen partial pressure, an oxygen ion-conducting solid electrolyte, and at least two measuring electrodes, the measuring electrodes and the reference electrode being mounted directly on the solid electrolyte and having electrical leads for connection and for take-away of electrical measurement signals. The solid electrolyte is constructed with a measurement gas side exposed to the gas mixture and a reference gas side separated from the gas mixture.

Abstract: A gas sensor and a process are provided for manufacturing a gas sensor with an oxygen ion-conducting solid electrolyte, which has a measurement gas side and a reference gas side and which separates a measurement gas space from a reference gas space, at least one measurement electrode being arranged on the measurement gas side of the solid electrolyte and at least one reference electrode being arranged on the reference gas side of the solid electrolyte, and with a support which is gas-permeable at least in the area of the electrodes. The problem presents itself of providing an economical gas sensor, in which the gas supply to the electrodes takes place through a gas-permeable support, as well as providing a simple process for manufacturing the gas sensor. The problem is solved for the gas sensor in that the oxygen ion-conducting solid electrolyte and the electrodes are constructed as thin layers and are arranged on the gas-permeable support.

Abstract: A method is provided for determining the oxygen content of a measurement gas using a sensor, as well as the use of the sensor according to the method. The problem presents itself of making available a method by which lambda can be determined as accurately and as simply as possible in a broad range of 0.8 to about 20. The problem is solved for the method in that the determination of the oxygen content of the measurement gas is performed by the first and the second measuring cells in a serial manner, wherein the oxygen content of the measurement gas is determined by the second measuring cell in a lambda range of 0.8 to 1.4 and by the first measuring cell in a lambda range of ≧1 to 20.

Abstract: A method for measurement of nitrogen oxides using a gas sensor. To reliably measure nitrogen oxides, the sensor has a reference electrode representing a constant oxygen partial pressure, at least two electrode pairs, with common a electrode associated with each pair of electrodes, and solid electrolytes arranged between the two electrodes of an electrode pair directly at the electrodes. The solid electrolyte between a first electrode pair is gas-permeable, while the solid electrolyte between a second electrode pair is gastight, whereby the second electrode pair is adapated for potentiometric or amperometric measurement of nitrogen oxides, and the first electrode pair is adapted for application of a current or a voltage to pump oxygen. The second electrode of the second electrode pair is constructed as a reference electrode on the reference gas side of the solid electrolyte of the second electrode pair. The sensor also has electrical leads for connection and for take-away of electric measurement signals.