A magnetic sensor includes: a magnetic converging plate; Hall elements disposed on one surface side of the magnetic converging plate; wires connecting with the Hall elements; and a signal processing circuit that connects with these wires to receive a signal from the Hall element. Between the Hall element and the signal processing circuit, the two wires cross while being spaced apart from each other in a depth direction of a substrate, and forms a compensation loop between a cross of the two wires and the circuit, and in a planar view as seen in a depth direction, at least part of a region occupied by the compensation loop is covered by the magnetic converging plate. The compensation loop compensates an induced electromotive force caused to the closed loop formed by the wires including the Hall element.

A semiconductor device includes a semiconductor substrate having a plurality of Hall elements formed therein, and a magnetic body formed on the semiconductor substrate and having a magnetic flux converging function. The contour in vertical cross-section of the magnetic body on the semiconductor substrate has an outer circumferential portion. At least a part of the outer circumferential portion has a portion having an approximate quadrant shape, and a portion contiguous to the approximate quadrant portion and substantially parallel to the semiconductor substrate.

The magnetic sensor includes a semiconductor substrate having Hall elements on a front surface of the semiconductor substrate, a conductive layer formed on a back surface of the semiconductor substrate, and a magnetic flux converging plate formed on the conductive layer. The magnetic flux converging plate is formed on the back surface of the semiconductor substrate through formation of the base conductive layer on the back surface of the semiconductor substrate, formation of a resist on the base conductive layer having an opening for forming the magnetic flux converging plate, formation of the magnetic flux converging plate in the opening of the resist by electroplating, removal of the resist, and removal of a part of the base conductive layer by etching with the magnetic flux converging plate as a mask.

An apparatus is provided which comprises: a magnetic junction having a magnet with a first magnetization; an interconnect adjacent to the magnetic junction, wherein the interconnect comprises an antiferromagnetic (AFM) material which is doped with a doping material (Pt, Ni, Co, or Cr) and a structure adjacent to the interconnect such that the magnetic junction and the structure are on opposite surfaces of the interconnect, wherein the structure comprises a magnet with a second magnetization substantially different from the first magnetization.

Disclosed examples provide wafer-level integration of magnetoresistive sensors and Hall-effect sensors in a single integrated circuit, in which one or more vertical and/or horizontal Hall sensors are formed on or in a substrate along with transistors and other circuitry, and a magnetoresistive sensor circuit is formed in the IC metallization structure.

A component with a magnetic field sensor. The electronic component is located in a semiconductor substrate or on the surface of the semiconductor substrate and is surrounded at least partially, preferably largely, by a trench in the semiconductor substrate. The trench is filled with a filling material.

The magnetic sensor includes a semiconductor substrate having Hall elements on a front surface of the semiconductor substrate, an adhesive layer formed on a back surface of the semiconductor substrate, and a magnetic flux converging plate formed on the adhesive layer. The magnetic flux converging plate is formed on the back surface of the semiconductor substrate through formation of the magnetic flux converging plate by electroplating on a base conductive layer formed on a plating substrate prepared separately from the semiconductor substrate, application of an adhesive for forming the adhesive layer onto a surface of the magnetic flux converging plate so that the magnetic flux converging plate adheres to the back surface of the semiconductor substrate, and peeling off of the plating substrate afterward from the base conductive layer formed on the magnetic flux converging plate.

A semiconductor device and a method of manufacturing the semiconductor device are provided. The semiconductor device includes a semiconductor substrate having a plurality of Hall elements formed therein, and a magnetic body formed on the semiconductor substrate and having a magnetic flux converging function. The contour in vertical-cross section of the magnetic body on the semiconductor substrate has an outer circumferential portion. At least a part of the outer circumferential portion has a curve-shaped portion and a portion substantially parallel to the semiconductor substrate. The magnetic body has at least a part of a structure made of non-magnetic substance embedded therein.

A memory cell is disclosed which includes a conductive layer, an insulating layer disposed atop the conducting layer, a semiconductor layer disposed atop the insulating layer, a first electrode coupled to the semiconductor layer, a second electrode coupled to the semiconductor layer, wherein the first and second electrodes are separated from one another and wherein the semiconductor layer extends beyond the first and second electrodes forming a first wing, a third electrode coupled to the conductive layer, a first magnetic tunnel junction (MTJ) disposed on the first wing, and a first read electrode coupled to the first MTJ.

A spin-orbit torque magnetoresistive random-access memory device formed by fabricating a first electrode upon a conductive contact of an underlying semiconductor device, forming a first vertical magnetoresistive random-access memory (MRAM) cell stack upon the first electrode, forming a spin-Hall-effect (SHE) layer above and in electrical contact with the MRAM cell stack, forming a protective dielectric layer covering a portion of the SHE layer, forming a second vertical MRAM cell stack above and in electrical contact with an exposed portion of the SHE layer, forming a second electrode above and in electrical contact with the second vertical MRAM cell stack, and forming a metal contact above and in electrical connection with the second electrode.