A sensing apparatus includes a device containing microwells and a switched capacitor circuit in which at least one of the sensing/storage capacitors is a capacitor that extends perpendicularly with respect to a semiconductor device layer containing field effect transistors. Capacitor structures extend into microwells or within a doped layer on a handle substrate. Ion generation within the microwells is sensed using the circuit.

Various bioFET sensor readout circuits and their methods of operation are described. A readout circuit includes a plurality of logic gates coupled in cascade, a delay extractor, and a counting module. Each logic gate of the plurality of logic gates includes at least one bioFET sensor. The delay extractor is designed to generate a pulse-width signal based on a time difference between an output signal from the plurality of logic gates and a reference signal. The counting module is designed to receive the pulse-width signal and output a digital count corresponding to a width of the pulse-width signal.

A sensor includes a substrate and a nanotube structure formed on top of the substrate. A body is formed on top of the substrate and surrounds the nanotube structure. A source contact is electrically coupled to a top portion of the nanotube structure. A drain contact is arranged on top of the substrate and is electrically coupled with a bottom portion of the nanotube structure. A gate contact is arranged on top of the nanotube structure. The gate contact is electrically is isolated from the top portion of the nanotube structure and electrically coupled with a middle portion of the nanotube structure. The top portion of the nanotube structure is exposed to an environment surrounding the sensor.

Methods and apparatus relating to very large scale FET arrays for analyte measurements. ChemFET (e.g., ISFET) arrays may be fabricated using conventional CMOS processing techniques based on improved FET pixel and array designs that increase measurement sensitivity and accuracy, and at the same time facilitate significantly small pixel sizes and dense arrays. Improved array control techniques provide for rapid data acquisition from large and dense arrays. Such arrays may be employed to detect a presence and/or concentration changes of various analyte types in a wide variety of chemical and/or biological processes. In one example, chemFET arrays facilitate DNA sequencing techniques based on monitoring changes in hydrogen ion concentration (pH), changes in other analyte concentration, and/or binding events associated with chemical processes relating to DNA synthesis.

An electrochemical sensor (10) for measuring biochemical parameters in the sap (L) of a plant (P), comprising: —a channel in which the sap (L) of a plant (P) flows; —a first electrically conductive filament (11) which crosses the channel; —a control electrode (12) which crosses the channel; wherein the channel comprises a conductor vessel (C) of a trunk (D) of the plant (P), and wherein the first filament (11) comprises a textile fiber (110) coated with a layer (111) of conductive polymer.

The disclosure describes methods, devices, and system that measure chemisorption potentiometrically for detection of target molecules. In one example, a device includes a semiconductor, an ionic conducting electronic insulator coupled to the semiconductor, a floating gate electrode comprising a first portion and a second portion, the first portion being coupled to the semiconductor via the ionic conducting electronic insulator, an aqueous buffer, and a primary gate electrode coupled to the second portion of the floating gate electrode via the aqueous buffer. The second portion of the floating gate electrode may comprise a probe configured to react with a target chemical composition of a molecule to detect the presence of the molecule. Reaction with the target chemical composition may change an electrical property of the device and indicate the presence of the molecule in the aqueous buffer.

Provided herein is a field-effect transistor based sensor for real-time detection of water contaminants and methods of use thereof.

It is recognized that, because of its unique properties, graphene can serve as an interface with biological cells that communicate by an electrical impulse, or action potential. Responding to a sensed signal can be accomplished by coupling a graphene sensor to a low power digital electronic switch that is activatable by the sensed low power electrical signals. It is further recognized that low power devices such as tunneling diodes and TFETs are suitable for use in such biological applications in conjunction with graphene sensors. While tunneling diodes can be used in diagnostic applications, TFETs, which are three-terminal devices, further permit controlling the voltage on one cell according to signals received by other cells. Thus, by the use of a biological sensor system that includes graphene nanowire sensors coupled to a TFET, charge can be redistributed among different biological cells, potentially with therapeutic effects.

A heterostructure comprising at least one carbon nanomembrane on top of at least one carbon layer, a method of manufacture of the heterostructure, and an electronic device, a sensor and a diagnostic device comprising the heterostructure. The heterostructure comprises at least one carbon nanomembrane on top of at least one carbon layer, wherein the at least one carbon nanomembrane has a thickness of 0.5 to 5 nm and the heterostructure has a thickness of 1 to 10 nm.

Provided is a semiconductor device A including: a first electrode 10; a second electrode 20; a semiconductor layer 30 in contact with the first electrode 10 and the second electrode 20; and a protective layer 40 configured to cover at least a part of a surface of the semiconductor layer 30, wherein the protective layer 40 includes a spinel oxide.