A semiconductor device including a CMOS process-based Hall sensor is provided. The semiconductor device which may include a N-type sensing region which is formed on a semiconductor substrate; P-type contact regions and N-type contact regions which are alternately formed in the N-type sensing region; a plurality of first trenches which are formed in contact with the P-type contact regions and have a first width; and a plurality of second trenches which separate the P-type contact regions and the N-type contact regions and have a second width less than the first width.

A semiconductor device includes a semiconductor substrate: a vertical Hall element formed in the semiconductor substrate, and having a magnetosensitive portion; a first excitation wiring disposed above the magnetosensitive portion, and configured to apply a first calibration magnetic field (M1) to the magnetosensitive portion; and second excitation wirings disposed above the magnetosensitive portion on one side and on another side of the first excitation wiring, respectively, along the first excitation wiring as viewed in plan view from immediately above a front surface of the semiconductor substrate, and configured to apply second calibration magnetic fields (M2) to the magnetosensitive portion.

An integrated rotation angle determining sensor unit in a measuring system for determining a rotation angle, comprising a shaft, rotatable around a rotation axis, having a transducer, a first semiconductor layer designed as a die being provided, which has an upper side arranged perpendicularly to the rotation axis and an underside and a first Hall sensor system monolithically formed in the first semiconductor layer, and a second semiconductor layer designed as a die being provided, which has an upper side arranged perpendicularly to the rotation axis and an underside and a second Hall sensor system monolithically formed in the second semiconductor layer, each Hall sensor system including at least one first Hall sensor and a second Hall sensor and a third Hall sensor.

A magnetic field magnetic field sensor and method of making the sensor. The sensor and method of making the sensor may comprise a material or structure that prevents the admission of light in certain wavelengths to enhance the stability of the magnetic field sensor over a period of time. The sensor and method of making the sensor may comprise an adsorption prevention layer which protects the semiconductor portion of the magnetic. The sensor may also comprise an insulating layer formed between semiconductor layers and a substrate layer.

A spin orbit logic (SOL) device includes a first electrically conductive layer; a layer comprising a ferroelectric material (FE layer) on the first electrically conductive layer; a second electrically conductive layer on the FE layer; and a spin orbit coupling (SOC) stack including a first layer (SOC1 layer) including a first SOC material, and a second layer (SOC2 layer) including a second SOC material, the SOC1 layer adjacent the FE layer.

A microelectronic device has a Hall sensor that includes a Hall plate in a semiconductor material. The Hall sensor includes contact regions in the semiconductor material, contacting the Hall plate. The Hall sensor includes an isolation structure with a dielectric material contacting the semiconductor material, on at least two opposite sides of each of the contact regions. The isolation structure is laterally separated from the contact regions by gaps. The Hall sensor further includes a conductive spacer over the gaps, the conductive spacer being separated from the semiconductor material by an insulating layer.

A multi-contact Hall plate having four contacts or a multiple of four contacts, wherein each of the contacts is arranged substantially equally distributed along an edge region of the Hall plate, and each of the contacts is connected to one of the four terminals.

A gateless P-N junction metrolog includes: a junction member including: a p-interface; and an n-interface disposed laterally and adjacent to the p-interface; and a p-n junction disposed at where the p-interface and n-interface contact; a drain electrode disposed on the junction member; a source electrode disposed on the junction member such that the source electrode is spaced apart from and opposing the drain electrode; an n-polymer disposed on the n-interface of the junction member; a p-polymer disposed on the p-interface of the junction member such that the n-polymer is interposed between the p-polymer and the n-interface; a mediation polymer disposed on the p-polymer such that the p-polymer is interposed between the mediation polymer and the junction member; and a mediator disposed in the mediation polymer and that receives electrons from the junction member in forming the p-interface.

A spin-orbit torque magnetoresistance effect element according to the present embodiment includes an element part including a first ferromagnetic layer, a second ferromagnetic layer, and a nonmagnetic layer positioned between the first ferromagnetic layer and the second ferromagnetic layer, a spin-orbit torque wiring positioned in a first direction with respect to the element part, facing the first ferromagnetic layer of the element part, and extending in a second direction, a first conductive part and a second conductive part facing the spin-orbit torque wiring at positions sandwiching the element part when viewed from the first direction, and a gate part positioned between the first conductive part and the second conductive part when viewed from the first direction, facing a second surface of the spin-orbit torque wiring on a side opposite to a first surface which faces the element part, and including a gate insulating layer and a gate electrode in order from a position near the spin-orbit torque wiring, in which the spin-orbit torque wiring includes a semiconductor to which a scattering element is added.

Data storage devices are provided. A data storage device includes a memory transistor on a substrate and a data storage structure electrically connected to the memory transistor. The data storage structure includes a magnetic tunnel junction pattern and a top electrode on the magnetic tunnel junction pattern. The top electrode includes a first top electrode and a second top electrode on the first top electrode, and the first and second top electrodes include the same metal nitride. The first top electrode includes first crystal grains of the metal nitride, and the second top electrode includes second crystal grains of the metal nitride. In a section of the top electrode, the number of the first crystal grains per a unit length is greater than the number of the second crystal grains per the unit length.