Provided are methods of manufacturing comprising providing a FET base structure, the FET base structure comprising a substrate, a drain and a source; and providing a channel layer on the FET base structure; and providing a first layer on the FET base structure. The first layer comprises a one-dimensional or two-dimensional material and is arranged on an upper surface of the channel layer so as to form a sensing surface of the FET. The step of providing the channel layer comprises forming the channel layer and subsequently transferring the channel layer onto the FET base structure. Alternatively or additionally, the step of providing the first layer on the FET base structure comprises forming the first layer and subsequently transferring the first layer onto the FET base structure.

A transistor having high field-effect mobility is provided. A transistor having stable electrical characteristics is provided. A transistor having low off-state current (current in an off state) is provided. Alternatively, a semiconductor device including the transistor is provided. The semiconductor device includes a first insulating film, an oxide semiconductor film over the first insulating film, a second insulating film over the oxide semiconductor film, and a conductive film overlapping with the oxide semiconductor film with the first insulating film or the second insulating film provided between the oxide semiconductor film and the conductive film. The composition of the oxide semiconductor film changes continuously between the first insulating film and the second insulating film.

Embodiments of the present disclosure describe a method of fabricating spin qubit device assemblies that utilize dopant-based spin qubits, i.e. spin qubit devices which operate by including a donor or an acceptor dopant atom in a semiconductor host layer. The method includes, first, providing a pair of gate electrodes over a semiconductor host layer, and then providing a window structure between the first and second gate electrodes, the window structure being a continuous solid material extending between the first and second electrodes and covering the semiconductor host layer except for an opening through which a dopant atom is to be implanted in the semiconductor host layer. By using a defined gate-first process, the method may address the scalability challenges and create a deterministic path for fabricating dopant-based spin qubits in desired locations, promoting wafer-scale integration of dopant-based spin qubit devices for use in quantum computing devices.

The present disclosure provides a reference electrode for providing a reference potential during measurement of a property of a sample. The reference electrode comprising: a reference electrode layer; and a reference layer provided over at least a part of the reference electrode layer and defining a sample receiving region which is separated from the reference electrode layer by the reference layer. In one embodiment, the reference layer comprises fluorinated or silanized graphene and/or fluorinated or silanized graphene oxide. Alternatively, the graphene or graphene oxide are functionalised or doped so as to form a super-hydrophobic reference layer.

A sensing assembly comprises for detecting a property of a sample comprises a field effect transistor (FET) configured to output a first signal indicative of a property of a sample comprises: a first layer providing a sensing surface; a channel provided below the first layer; and a drain and a source in electrical communication with the channel. The sensing assembly may further comprise a gate provided below the first layer and the first layer comprises a one-dimensional or two-dimensional material. Alternatively or additionally, the first layer comprises N-polar hexagonal boron nitride (hBN).

A CMOS-based sensing device includes a substrate including an etched portion and a first region located on the substrate. The first region includes a membrane region formed over an area of the etched portion of the substrate, a flow sensor formed within the membrane region and a pressure sensor formed within the membrane region.

A semiconductor wafer having a main surface and a rear surface opposite from the main surface is provided. A die singulation preparation step is performed in kerf regions of the semiconductor wafer. The kerf regions enclose a plurality of die sites. The die singulation preparation step includes forming one or more preliminary kerf trenches between at least two immediately adjacent die sites. The method further includes forming active semiconductor devices in the die sites, and singulating the semiconductor wafer in the kerf regions thereby providing a plurality of discrete semiconductor dies from the die sites. The one or more preliminary kerf trenches are unfilled during the singulating, and the singulating includes removing semiconductor material from a surface of the semiconductor wafer that is between opposite facing sidewalls of the one or more preliminary kerf trenches.

A semiconductor wafer having a main surface and a rear surface opposite from the main surface is provided. A die singulation preparation step is performed in kerf regions of the semiconductor wafer. The kerf regions enclose a plurality of die sites. The die singulation preparation step includes forming one or more preliminary kerf trenches between at least two immediately adjacent die sites. The method further includes forming active semiconductor devices in the die sites, and singulating the semiconductor wafer in the kerf regions thereby providing a plurality of discrete semiconductor dies from the die sites. The one or more preliminary kerf trenches are unfilled during the singulating, and the singulating includes removing semiconductor material from a surface of the semiconductor wafer that is between opposite facing sidewalls of the one or more preliminary kerf trenches.

We disclose herein a CMOS-based sensing device comprising a substrate comprising an etched portion, a first region located on the substrate, wherein the first region comprises a membrane region formed over an area of the etched portion of the substrate, a flow sensor formed within the membrane region and a pressure sensor formed within the membrane region.

A semiconductor structure, such as a group III nitride-based semiconductor structure is provided. The semiconductor structure includes a cavity containing semiconductor layer. The cavity containing semiconductor layer can have a thickness greater than two monolayers and a multiple cavities. The cavities can have a characteristic size of at least one nanometer and a characteristic separation of at least five nanometers.