Structures for a Hall sensor and methods of forming a structure for a Hall sensor. The structure includes a semiconductor body having a top surface and a sloped sidewall defining a Hall surface that intersects the top surface. The structure further includes a well in the semiconductor body and multiple contacts in the semiconductor body. The well has a section positioned in part beneath the top surface and in part beneath the Hall surface. Each contact is coupled to the section of the well beneath the top surface of the semiconductor body.

A magnetic sensor has a pair of Hall elements formed in spaced-apart relationship on a front surface of a semiconductor substrate. A die pad is bonded to a back surface of the semiconductor substrate and overlaps the Hall elements. The die pad has formed therein a magnetic converging plate holder having a recessed portion, and a magnetic converging plate having the same shape and size as the recessed portion is fitted in the recessed portion of the magnetic converging plate holder.

Methods for doping an active Hall effect region of a Hall effect device in a semiconductor substrate, and Hall effect devices having a doped active Hall effect region are provided. A method includes forming a first doping profile of a first doping type in a first depth region of the active Hall effect region by means of a first implantation with a first implantation energy level, forming a second doping profile of the first doping type in a second depth region of the active Hall effect region by means of a second implantation with a second implantation energy level, and forming an overall doping profile of the active Hall effect region by annealing the semiconductor substrate with the active Hall effect region having the first and the second doping profile.

In one aspect, a vertical Hall effect sensor includes a semiconductor wafer having a first conductivity type and a plurality of semiconductive electrodes disposed on the semiconductor wafer. The plurality of semiconductive electrodes have the first conductivity type and include a source electrode, a first sensing electrode and a second sensing electrode, arranged such that the source electrode is between the first sensing electrode and the sensing electrode and a first drain electrode and a second drain electrode, arranged such that the first sensing electrode, second sensing electrode, and source electrode are between the first drain electrode and the second drain electrode. The vertical Hall effect sensor also includes a plurality of semiconductor fingers disposed on the semiconductor wafer and interdigitated with the plurality of semiconductive electrodes, the semiconductor fingers having a second conductivity type.

Hybrid Hall Effect Devices implemented with Spin Transfer Torque write capability are configured as magnetoelectronic (ME) devices. These devices are useable as circuit building blocks in reconfigurable processing systems, including as logic circuits, non-volatile switches and memory cells.

Disclosed is a magnetic device including a spin sinker. The magnetic device includes a storage medium, a spin sinker, and a read node. The storage medium receives an in-plane current from outside and generates a self-generated spin current that perpendicularly flows to a charge current, thereby controlling a data structure with the self-generated spin current. The spin sinker receives and attenuates the spin current. The read node measures a magnetoresistance of a data structure through the storage medium. The storage medium is made of a magnetic metal and the spin sinker is made of a magnetic insulating material.

Spin orbit torque (SOT) devices with topological insulator (TI) and heavy metal insert are described. In an example, an integrated circuit structure includes a spin orbit coupling (SOC) interconnect including a TI material. A magnetic layer is above the SOC interconnect. An insert layer includes a heavy metal between and in contact with the TI material and the magnetic layer.

A coupler is disclosed that employs hall-effect sensing technology. Specifically, the coupler is configured to produce an output voltage by converting the magnetic field generated by a current conductor at an input side. The output and input sides may be electrically isolated from one another but may be coupled via the hall-effect sensing technology, such as a hall-effect sensor. The output and input sides may be provided in an overlapping configuration.

Dirac semimetals, methods for modulating charge carrying density and/or band gap in a Dirac semimetal, devices including a Dirac semimetal layer, and methods for forming a Dirac semimetal layer on a substrate are described.

A miniature oxygen sensor makes use of paramagnetic properties of oxygen gas to provide a fast response time, low power consumption, improved accuracy and sensitivity, and superior durability. The miniature oxygen sensor disclosed maintains a sample of ambient air within a micro-channel formed in a semiconductor substrate. O.sub.2 molecules segregate in response to an applied magnetic field, thereby establishing a measurable Hall voltage. Oxygen present in the sample of ambient air can be deduced from a change in Hall voltage with variation in the applied magnetic field. The magnetic field can be applied either by an external magnet or by a thin film magnet integrated into a gas sensing cavity within the micro-channel. A differential sensor further includes a reference element containing an unmagnetized control sample. The miniature oxygen sensor is suitable for use as a real-time air quality monitor in consumer products such as smart phones.