A spin-current magnetization rotational element includes a spin orbit torque wiring extending in a first direction and a first ferromagnetic layer disposed in a second direction intersecting the first direction of the spin orbit torque wiring, the spin orbit torque wiring having a first surface positioned on the side where the first ferromagnetic layer is disposed, and a second surface opposite to the first surface, and the spin orbit torque wiring has a second region on the first surface outside a first region in which the first ferromagnetic layer is disposed, the second region being recessed from the first region to the second surface side.

A method for fabricating semiconductor device includes the steps of first providing a substrate having a magnetic random access memory (MRAM) region and a logic region, forming a first inter-metal dielectric (1MB) layer on the substrate, forming a first metal interconnection and a second metal interconnection in the first IMD layer on the MRAM region, forming a spin orbit torque (SOT) layer on the first metal interconnection and the second metal interconnection, forming a magnetic tunneling junction (MTJ) stack on the SOT layer, forming a hard mask on the MTJ stack, using the hard mask to pattern the MTJ stack for forming the MTJ, forming the cap layer on the SOT layer and the hard mask, and patterning the cap layer and the SOT layer.

A method for fabricating semiconductor device includes the steps of first providing a substrate having a magnetic random access memory (MRAM) region and a logic region, forming a first inter-metal dielectric (1MB) layer on the substrate, forming a first metal interconnection and a second metal interconnection in the first IMD layer on the MRAM region, forming a spin orbit torque (SOT) layer on the first metal interconnection and the second metal interconnection, forming a magnetic tunneling junction (MTJ) stack on the SOT layer, forming a hard mask on the MTJ stack, using the hard mask to pattern the MTJ stack for forming the MTJ, forming the cap layer on the SOT layer and the hard mask, and patterning the cap layer and the SOT layer.

A chip package, a chip package system, a method of manufacturing a chip package, and a method of operating a chip package including: a first sensor configured to measure a magnetic field component up to a maximum magnetic field value; a second sensor configured to measure the magnetic field component beyond the maximum magnetic field value; and a circuit coupled to the first sensor and the second sensor and configured to receive at least one sensor signal from at least one of the first sensor and the second sensor, wherein the circuit is further configured to select the first sensor or the second sensor to measure the magnetic field component based on the received sensor signal.

The present disclosure generally relates to spin-orbit torque (SOT) magnetic tunnel junction (MTJ) devices comprising a doped bismuth antimony (BiSbE) layer having a (012) orientation. The devices may include magnetic write heads, read heads, or MRAM devices. The dopant in the BiSbE layer enhances the (012) orientation. The BiSbE layer may be formed on a texturing layer to ensure the (012) orientation, and a migration barrier may be formed over the BiSbE layer to ensure the antimony does not migrate through the structure and contaminate other layers. A buffer layer and interlayer may also be present. The buffer layer and the interlayer may each independently be a single layer of material or a multilayer of material. The buffer layer and the interlayer inhibit antimony (Sb) migration within the doped BiSbE layer and enhance uniformity of the doped BiSbE layer while further promoting the (012) orientation of the doped BiSbE layer.

The present disclosure generally relates to spin-orbit torque (SOT) magnetic tunnel junction (MTJ) devices comprising a doped bismuth antimony (BiSbE) layer having a (012) orientation. The devices may include magnetic write heads, read heads, or MRAM devices. The dopant in the BiSbE layer enhances the (012) orientation. The BiSbE layer may be formed on a texturing layer to ensure the (012) orientation, and a migration barrier may be formed over the BiSbE layer to ensure the antimony does not migrate through the structure and contaminate other layers. A buffer layer and interlayer may also be present. The buffer layer and the interlayer may each independently be a single layer of material or a multilayer of material. The buffer layer and the interlayer inhibit antimony (Sb) migration within the doped BiSbE layer and enhance uniformity of the doped BiSbE layer while further promoting the (012) orientation of the doped BiSbE layer.

A memory apparatus includes a first electrode having a spin orbit material. The memory apparatus further includes a first memory device on a portion of the first electrode and a first dielectric adjacent to a sidewall of the first memory device. The memory apparatus further includes a second memory device on a portion of the first electrode and a second dielectric adjacent to a sidewall of the second memory device. A second electrode is on and in contact with a portion of the first electrode, where the second electrode is between the first memory device and the second memory device. The second electrode has a lower electrical resistance than an electrical resistance of the first electrode. The memory apparatus further includes a first interconnect structure and a second interconnect, each coupled with the first electrode.

A memory apparatus includes a first electrode having a spin orbit material. The memory apparatus further includes a first memory device on a portion of the first electrode and a first dielectric adjacent to a sidewall of the first memory device. The memory apparatus further includes a second memory device on a portion of the first electrode and a second dielectric adjacent to a sidewall of the second memory device. A second electrode is on and in contact with a portion of the first electrode, where the second electrode is between the first memory device and the second memory device. The second electrode has a lower electrical resistance than an electrical resistance of the first electrode. The memory apparatus further includes a first interconnect structure and a second interconnect, each coupled with the first electrode.

The invention concerns the field of electronics and materials science and relates to components on flexible substrates, as are for example used as sensors or actuators in the automotive industry, mechanical engineering or electronics, and to a method for the production thereof.

The object of the present invention is the specification of components on flexible substrates, the physical and in particular electrical properties of which have long-term stability, and the specification of a cost-efficient and simple method for the production thereof.

The object is attained with components on flexible substrates, composed of a flexible substrate having a barrier layer arranged at least partially thereon, on which layer a components layer is at least partially positioned.

A magnetic memory device includes first, second, and third conductor layers, and a memory cell that is coupled to the first, second, and third conductor layers. The memory cell includes a fourth conductor layer and a magnetoresistance effect element. The fourth conductor layer includes first, second, and third portions coupled to the first, second, and third conductor layers, respectively. The third portion is between the first and second portions. The magnetoresistance effect element is coupled between a third conductor and the fourth conductor layer. The fourth conductor layer includes a magnetic layer and a non-magnetic layer that is between the magnetic layer and the magnetoresistance effect element. The magnetic layer has a first saturation magnetization during a standby state or a read state of the memory cell, and has a second saturation magnetization larger than the first saturation magnetization during a write state of the memory cell.