Abstract: The invention provides a sensor for detecting a bioanalyte, comprising: a substrate; a pair of terminal electrodes disposed on the substrate in mutually spaced apart and opposing relation; and a sensing element, between and in electrical contact with the pair of terminal electrodes, wherein the sensing element comprises: (i) a semiconducting portion of the substrate, wherein the semiconducting portion comprises a high-resistivity non-oxide semiconductor and wherein a conduction path between the terminal electrodes passes through the semiconducting portion; and (ii) a bioanalyte binding site on a surface of the semiconducting portion, wherein binding of a bioanalyte to the bioanalyte binding site causes a change in electrical resistance of the sensor.

Abstract: The invention provides a sensor for detecting a nucleic acid, comprising: a substrate; a pair of terminal electrodes disposed on the substrate in mutually spaced apart and opposing relation; and a sensing element, between and in electrical contact with the pair of terminal electrodes, wherein the sensing element comprises: (i) a semiconducting portion of the substrate, wherein a conduction path between the terminal electrodes passes through the semiconducting portion; and (ii) an oligonucleotide on a surface of the semiconducting portion, the oligonucleotide being complementary to the nucleic acid to be detected, wherein hybridisation of the nucleic acid with the oligonucleotide leads to a change in resistance of the sensor.

Abstract: The present disclosure generally relates to an electronic strain sensor, a system incorporating the sensor, and a method of manufacturing the sensor. The present disclosure also relates to methods of measuring one or more physiological parameters of a living subject, or methods of diagnosing a sleep-related disorder of a living subject, the methods comprising sensing a signal produced by the living subject with the electronic strain sensor or system. The strain sensor comprises: an electrode layer printed on a substrate, a sensing layer printed on a portion of the electrode layer, and an encapsulation layer encapsulating the electrode and sensing layers. The electrode layer exhibits a sheet resistance less than that of the sensing layer, and the sensing layer is in direct contact with the electrode layer. The sensor's electrical resistance can be increased through forming microscopic cracks in the sensing layer in response to forces applied to the sensor.

Abstract: A sensor for discriminating between wavelength regions in an electromagnetic spectrum is disclosed. The sensor comprising a substrate, a sensing element supported on a surface of the substrate, and at least one pair of terminal electrodes disposed on the substrate surface in mutually spaced apart and opposing relation, and in electrical contact with the sensing element, wherein the sensing element is responsive to electromagnetic radiation to yield a change in photocurrent measured between the terminal electrodes as a function of an intensity of the electromagnetic radiation impinging thereon, wherein a positive dependency on the intensity corresponds to a first wavelength region and a negative dependency on the intensity corresponds to a second wavelength region.

Abstract: An imaging device described herein for capturing image data comprises an optical sensor responsive to electromagnetic radiation, wherein the sensor exhibits a photo-memory effect causing the sensor to act as a short-term memory device; an exposure control device configured to adopt a first mode, wherein electromagnetic radiation reaches the sensor and a second mode, wherein electromagnetic radiation is restricted from reaching the sensor; a processor configured to receive sensor data from the sensor, and to cause the exposure control device to selectively adopt the first mode and the second mode; and a long term memory device accessible to the processor, wherein the processor is configured to read executable instructions from the long term memory and to write sensor data to the long term memory. Data stored in the sensor acting as a short-term memory device is erasable by exposing the photo-sensor to electromagnetic radiation.

Abstract: This application discloses a device for detecting nicotine. The device includes a nicotine sensor comprising vanadium oxide (VO2), a processor and circuitry configured to detect a change in the electrical resistance of the nicotine sensor. The processor is configured to receive, from the circuitry, a signal representative of the detected change in the electrical resistance of the nicotine sensor and output data based on the detected change in electrical resistance of the nicotine sensor. A system and method for detecting nicotine are also disclosed.

Abstract: The present invention provides a sensor for detecting a bioanalyte, comprising: a substrate; a pair of terminal electrodes disposed on the substrate in mutually spaced apart and opposing relation; and a non-insulating sensing element applied to a surface of the substrate, between and in electrical contact with the pair of terminal electrodes wherein the sensing element provides a conduction path between the terminal electrodes, wherein the sensing element comprises an oxygen-deficient metal oxide layer and a bioanalyte binding site, and wherein when a voltage is applied across the sensor, an electrical signal is generated that is proportional to a change in conductance of the sensing element corresponding to binding of a bioanalyte to the bioanalyte binding site.

Abstract: Method for fabricating a crystalline vanadium oxide (VO2) film comprising the steps of: a) depositing an amorphous VO2 film on a substrate by pulsed DC magnetron sputtering using a vanadium target, wherein the substrate is exposed to a sputtering gas comprising an inert process gas and oxygen (O2), and the substrate has a temperature of less than about 50° C.; and b) annealing the deposited amorphous VO2 film to crystallise the amorphous VO2 film into a crystalline VO2 film that exhibits an insulator-metal transition. The disclosed method for fabricating a crystalline VO2 film may be suitable for a broad range of substrates.

Abstract: A sensor for discriminating between wavelength regions in an electromagnetic spectrum is disclosed. The sensor comprising a substrate, a sensing element supported on a surface of the substrate, and at least one pair of terminal electrodes disposed on the substrate surface in mutually spaced apart and opposing relation, and in electrical contact with the sensing element, wherein the sensing element is responsive to electromagnetic radiation to yield a change in photocurrent measured between the terminal electrodes as a function of an intensity of the electromagnetic radiation impinging thereon, wherein a positive dependency on the intensity corresponds to a first wavelength region and a negative dependency on the intensity corresponds to a second wavelength region.

Abstract: A memristor device is disclosed comprising: a first electrode; a second electrode; a cathode metal layer disposed on a surface of the first electrode; and an active region disposed between and in electrical contact with the second electrode and the cathode metal layer, the active region comprising at least one layer of an amorphous metal oxide, wherein when a switching voltage is applied between the first and second electrodes, the active region exhibits a resistive switching behaviour. A method of fabricating a memristor device is also disclosed.

Abstract: Method for fabricating a crystalline vanadium oxide (VO2) film comprising the steps of: a) depositing an amorphous VO2 film on a substrate by pulsed DC magnetron sputtering using a vanadium target, wherein the substrate is exposed to a sputtering gas comprising an inert process gas and oxygen (O2), and the substrate has a temperature of less than about 50° C.; and b) annealing the deposited amorphous VO2 film to crystallise the amorphous VO2 film into a crystalline VO2 film that exhibits an insulator-metal transition. The disclosed method for fabricating a crystalline VO2 film may be suitable for a broad range of substrates.

Abstract: A memristor device is disclosed comprising: a first electrode; a second electrode; a cathode metal layer disposed on a surface of the first electrode; and an active region disposed between and in electrical contact with the second electrode and the cathode metal layer, the active region comprising at least one layer of an amorphous metal oxide, wherein when a switching voltage is applied between the first and second electrodes, the active region exhibits a resistive switching behaviour. A method of fabricating a memristor device is also disclosed.

Abstract: In general, this disclosure is directed to a flexible or stretchable sensor and a method of detecting a substance and/or electromagnetic radiation using said sensor. The sensor comprises a flexible or stretchable substrate, a pair of terminal electrodes disposed on the flexible or stretchable substrate in mutually spaced apart and opposing relation, and a sensing element applied to the flexible or stretchable substrate, between and in electrical contact with the pair of terminal electrodes, wherein the sensing element is responsive to a substance and/or electromagnetic radiation impinging thereon, and wherein when a voltage is applied across the sensor, an electrical signal is generated that is proportional to a resistance value corresponding to a sensing of the substance and/or electromagnetic radiation impinging on the sensing element.

Abstract: In general, this disclosure is directed to a flexible or stretchable sensor and a method of detecting a substance and/or electromagnetic radiation using said sensor. The sensor comprises a flexible or stretchable substrate, a pair of terminal electrodes disposed on the flexible or stretchable substrate in mutually spaced apart and opposing relation, and a sensing element applied to the flexible or stretchable substrate, between and in electrical contact with the pair of terminal electrodes, wherein the sensing element is responsive to a substance and/or electromagnetic radiation impinging thereon, and wherein when a voltage is applied across the sensor, an electrical signal is generated that is proportional to a resistance value corresponding to a sensing of the substance and/or electromagnetic radiation impinging on the sensing element.