Abstract: In an electrochemical sensor, a peak is detected by grouping data points in windows and detecting two or three windows between which the slope of the data changes sign. the peak can be more precisely detected by detecting the highest data point in the two or three windows.

Abstract: A method of confining an electroactive substance within an electrochemical cell in the form of a receptacle, said method that includes (a) providing an electrochemical cell in the form of a receptacle, the receptacle having a first open part to allow entry of a sample into the receptacle, and a second open part to allow escape of air displaced by the entering sample, the electrochemical cell having a working electrode and a counter electrode; (b) providing an electroactive substance, which substance is contained within the receptacle; (c) providing a permeable or semi-permeable membrane, including one or more layers, covering the first open part of the receptacle; and (d) inserting the sample into the receptacle through the membrane, such that (1) the electroactive substance and (2) the sample, are in contact with each other and with said working electrode; wherein the electroactive substance is confined within the receptacle during step (d).

Abstract: A method is provided to manufacture an electrochemical sensor that includes a strip with a receptacle formed therein, and a working electrode located in a wall of the receptacle. The method includes the steps of applying a working electrode layer onto a first insulating material, and applying a dielectric layer, formed by a first dielectric layer and a second dielectric layer, onto at least a part of the working electrode layer to form a laminate. A hole or well is created in the laminate, wherein the hole or well passes through the working electrode layer and a first surface of the laminate. The method further includes applying a pseudo reference electrode layer onto at least a part of the first surface of the laminate, and optionally attaching a base to a second surface of the laminate to produce a bonded article.

Abstract: The invention concerns an electrochemical cell which, either alone or together which a substrate onto which it is placed, is in the form of a receptacle. The electrochemical cell contains a working electrode and a counter electrode, the working electrode being in a wall of the receptacle. At least one of the electrodes has at least one dimension of less than 50 ?m. The electrochemical cell is principally intended for use as a micro-electrode suitable for screening water, blood, urine or other biological or non-biological fluids.

Abstract: An apparatus and method provide for automated converting of a web of a thin patterned catalyst-coated membrane to separate membrane sheets for fuel cell assembly. The membrane typically has a thickness of about one thousandth of an inch. Automated web converting involves transporting, with use of a movable vacuum, an end portion of the membrane web from a first location to a second location. With use of respective first and second vacuums at the first and second locations, and after removal of the movable vacuum, the end portion of the membrane web is releasably secured at the first and second locations. The membrane web is cut within a gap defined between a single catalyst pattern of the membrane web end portion and an adjacent catalyst pattern to produce a membrane sheet. The membrane sheet is precisely positioned to a desired orientation to facilitate subsequent processing of the membrane sheet.

Abstract: An apparatus and method provide for automated converting of a web of a thin patterned catalyst-coated membrane to separate membrane sheets for fuel cell assembly. The membrane typically has a thickness of about one thousandth of an inch. Automated web converting involves transporting, with use of a movable vacuum, an end portion of the membrane web from a first location to a second location. With use of respective first and second vacuums at the first and second locations, and after removal of the movable vacuum, the end portion of the membrane web is releasably secured at the first and second locations. The membrane web is cut within a gap defined between a single catalyst pattern of the membrane web end portion and an adjacent catalyst pattern to produce a membrane sheet. The membrane sheet is precisely positioned to a desired orientation to facilitate subsequent processing of the membrane sheet.

Abstract: An apparatus and method provide for automated converting of a web of a thin patterned catalyst-coated membrane to separate membrane sheets for fuel cell assembly. The membrane typically has a thickness of about one thousandth of an inch. Automated web converting involves transporting, with use of a movable vacuum, an end portion of the membrane web from a first location to a second location. With use of respective first and second vacuums at the first and second locations, and after removal of the movable vacuum, the end portion of the membrane web is releasably secured at the first and second locations. The membrane web is cut within a gap defined between a single catalyst pattern of the membrane web end portion and an adjacent catalyst pattern to produce a membrane sheet. The membrane sheet is precisely positioned to a desired orientation to facilitate subsequent processing of the membrane sheet.