A electronic device and a fabrication method is provided. The electronic device having a first electrode and a second electrode. A nano-gap is formed between first and second electrode. The first electrode, the second electrode and the gap may be located in the same layer of the device.

The described embodiments may provide a chemical detection circuit that may comprise a plurality of first output circuits at a first side and a plurality of second output circuits at a second side of the chemical detection circuit. The chemical detection circuit may further comprise a plurality of tiles of pixels each placed between respective pairs of first and second output circuits. Each tile may include four quadrants of pixels. Each quadrant may have columns with designated first columns interleaved with second columns. Each first column may be coupled to a respective first output circuit in first and second quadrants, and to a respective second output circuit in third and fourth quadrants. Each second column may be coupled to a respective second output circuit in first and second quadrants, and to a respective first output circuit in third and fourth quadrants.

The described embodiments may provide a chemical detection circuit. The chemical detection circuit may comprise a column of chemically-sensitive pixels. Each chemically-sensitive pixel may comprise a chemically-sensitive transistor, and a row selection device. The chemical detection circuit may further comprise a column interface circuit coupled to the column of chemically-sensitive pixels and an analog-to-digital converter (ADC) coupled to the column interface circuit. Each column interface circuit and column-level ADC may be arrayed with other identical circuits and share critical resources such as biasing and voltage references, thereby saving area and power.

A field effect transistor sensor includes: a source-drain channel, a semiconductor layer on said source-drain channel, a first gate electrode arranged above said semiconductor layer, a first well enclosing said source-drain channel, said semiconductor layer and said first gate electrode, the first well being configured to be filled, in use, with a first liquid, particularly a gating electrolyte, a second gate electrode arranged above the first gate electrode and exposed to an interior of the first well. Also disclosed is an array device including an array of field effect transistor sensors according to the above.

The present invention describes a method for chemical sensing and biomolecular diagnostics with a microelectronic sensor based on the combination of an open-gate pseudo-conductive high-electron mobility transistor and a Vivaldi antenna installed in the open gate area of the transistor and operated in the sub-THz and THz frequency range.

A ratiometric vapor sensor is described that includes a first sensor and a second sensor. The first sensor includes a first semiconductor component comprising a vapor-sensitive semiconducting organic compound, while the second sensor includes a second semiconductor component comprising a modified vapor-sensitive semiconducting organic compound including a modifying organic group. The ratiometric vapor sensor can be used to detect the presence of a vapor such as nitrogen dioxide, and determine the concentration of the vapor by comparing the outputs of electrodes connected to the first and second sensor.

The described embodiments may provide a chemical detection circuit. The chemical detection circuit may comprise a column of chemically-sensitive pixels. Each chemically-sensitive pixel may comprise a chemically-sensitive transistor, and a row selection device. The chemical detection circuit may further comprise a column interface circuit coupled to the column of chemically-sensitive pixels and an analog-to-digital converter (ADC) coupled to the column interface circuit. Each column interface circuit and column-level ADC may be arrayed with other identical circuits and share critical resources such as biasing and voltage references, thereby saving area and power.

In one embodiment, a chemical sensor is described. The chemical sensor includes a chemically-sensitive field effect transistor including a floating gate conductor having an upper surface, a first opening extending through a first material and through a portion of a second material located on the first material and a second opening extending from the bottom of the first opening to the top of a liner layer located on the upper surface of the floating gate conductor.

A biosensor with a detection transistor of a metal-semiconductor field-effect (MESFET) type, for detecting a target substance. The detection transistor has an isolating substrate, a source electrode, a drain electrode, a first gate electrode, a channel for transmitting a drain-source current between the source electrode and the drain electrode, the channel being made of an oxide semiconductor, arranged on the isolating substrate and having the source electrode and the drain electrode arranged thereon, a sensitive substrate connected to the first gate electrode and including functionalization species for bonding the target substance, such that the first gate electrode connected with said substrate is sensitive to the target substance, and a second gate electrode arranged on the isolating substrate, physically separated from the first gate electrode by the channel, positioned opposite to the first gate electrode and aimed to modulate the drain-source current of the channel.

A electronic device and a fabrication method is provided. The electronic device having a first electrode and a second electrode. A nano-gap is formed between first and second electrode. The first electrode, the second electrode and the gap may be located in the same layer of the device. A two-dimensional layer of graphene may cover the gap.