Abstract: Embodiments of present invention provide a method of improving yield of making MRAM arrays. More specifically, the method includes receiving an MRAM array; identifying a weak MRAM cell from the MRAM array wherein the weak MRAM cell includes an access transistor; and modifying the access transistor. In one embodiment, modifying the access transistor includes performing a hot carrier injection into a gate dielectric layer of the access transistor.

Abstract: Embodiments of the invention include a method for fabricating a magnetoresistive random-access memory (MRAM) structure and the resulting structure. A first type of metal is formed on an interlayer dielectric layer with a plurality of embedded contacts, where the first type of metal exhibits spin Hall effect (SHE) properties. At least one spin-orbit torque (SOT) MRAM cell is formed on the first type of metal. One or more recesses surrounding the at least one SOT-MRAM cell are created by recessing exposed portions of the first type of metal. A second type of metal is formed in the one or more recesses, where the second type of metal has lower resistivity than the first type of metal.

Abstract: A second BEOL layer including a via dielectric layer surrounding a via including an upper metal stud and a lower metal stud separated by a liner, and a magnetic tunnel junction (MTJ) stack aligned above the via. A first back end of line (BEOL) layer including a BEOL dielectric layer surrounding a BEOL metal layer, a second BEOL layer including a via dielectric layer surrounding a via including an upper metal stud and a lower metal stud separated by a liner, a magnetic tunnel junction (MTJ) stack aligned above the via. Forming a via dielectric layer as a second back end of line (BEOL) layer, an opening, a lower metal stud in the opening, a liner on the lower metal stud and on exposed side surfaces of the opening, an upper metal stud in remaining portions of the opening, and forming a magnetic tunnel junction (MTJ) stack aligned above.

Abstract: A magnetic shielding structure for protecting an MRAM array from adverse switching effects due to external magnetic fields of neighboring devices is provided. The magnetic shielding structure includes a bottom magnetic shield material-containing layer and a top magnetic shield material-containing layer within the MRAM array. The bottom and top magnetic shield material-containing layers can be connected by a vertical magnetic shield containing-material layer that is located near each end of the bottom and top magnetic shield material-containing layers. The bottom magnetic shield material-containing layer is located beneath a MTJ pillar of each MRAM device, but above, bottom electrically conductive structures that are in electrical contact with the MRAM devices. The top magnetic shield material-containing layer is located above the MRAM devices, and is located laterally adjacent to, but not above or below, top electrically conductive structures that are also in electrical contact with the MRAM devices.

Abstract: A cross-point SOT-MRAM cell includes: a first SHE write line; a second SHE write line non-colinear to the first SHE write line; a cross-point free layer comprising a first free layer, a second free layer, and a dielectric layer disposed between the first and the second free layers, the cross-point free layer configured to store a magnetic bit and located between and in contact with both the first SHE write line and the second SHE write line; and a remote sensing MTJ located in a vicinity of the cross-point free layer, wherein a free layer sensor of the remote sensing MTJ is in contact with one of the first SHE write line and the second SHE write line.

Abstract: The present disclosure is drawn to, among other things, a method of managing a memory device. In some aspects, the method includes determining whether a first address for a page in a first memory region is mapped in a map table, setting a target address as a second address identified in the map table as being mapped to the first address, setting the target address as the first address, determining a number of bits that fail in each word of a plurality of first-layer error correction code (ECC) words for the target address, and adding the target address to the map table, writing-back contents from the target address to a repair address in the first memory region, and updating the map table by mapping the target address to the repair address.

Abstract: The present disclosure is drawn to, among other things, a configuration bit including at least four resistive elements and a voltage amplifier. At least two first resistive elements may be electrically connected in series via a first electrode and at least two second resistive elements may be electrically connected in series via a second electrode. The at least two first resistive elements may be electrically connected in parallel to the at least two second resistive elements via a third electrode and a fourth electrode. The first electrode and the second electrode may be electrically connected to a voltage supply. The third electrode and the fourth electrode may be electrically connected to an input of the voltage amplifier.

Abstract: A device includes a Magnetic Tunnel Junction (MTJ) memory element comprising, a reference layer, a free layer, and a magnetic tunneling layer between the reference layer and the free layer; and a pair of magneto-electric controlling layers, which have in-plane uniaxial anisotropy, wherein the pair of magneto-electric controlling layers are disposed below the free layer.

Abstract: A via interconnect structure for an MRAM device is provided. The via interconnect structure includes an interlayer dielectric layer having a via formed therein, a magnetic metal layer formed in the via, the magnetic metal layer having a cavity formed therein, and a nonmagnetic metal layer formed in the cavity of the magnetic metal layer. The magnetic metal layer is configured such that magnetization vectors of the magnetic metal layer are least substantially in-plane relative to an MRAM stack structure of the MRAM device.

Abstract: The present disclosure is drawn to, among other things, a method of managing a memory device. In some aspects, the method includes determining whether a first address for a page in a first memory region is mapped in a map table, setting a target address as a second address identified in the map table as being mapped to the first address, setting the target address as the first address, determining a number of bits that fail in each word of a plurality of first-layer error correction code (ECC) words for the target address, and adding the target address to the map table, writing-back contents from the target address to a repair address in the first memory region, and updating the map table by mapping the target address to the repair address.

Abstract: Embodiments of present invention provide a method of improving yield of making MRAM arrays. More specifically, the method includes receiving an MRAM array; identifying a weak MRAM cell from the MRAM array wherein the weak MRAM cell includes an access transistor; and modifying the access transistor. In one embodiment, modifying the access transistor includes performing a hot carrier injection into a gate dielectric layer of the access transistor.

Abstract: An approach for providing a semiconductor structure for a stacked magnetoresistive random-access memory (MRAM) device that includes a first magnetic tunnel junction on a bottom electrode and at least one second magnetic tunnel junction above the first magnetic tunnel junction. The semiconductor structure includes the first magnetic tunnel junction is a voltage-controlled magnetic anisotropy (VCMA) magnetic tunnel junction of a voltage-controlled magnetic anisotropy (VCMA) MRAM device. The VCMA-MRAM device is composed of a first reference layer, a first tunnel barrier layer, and a first free layer. The semiconductor structure includes the second magnetic tunnel junction that is a spin-transfer torque (STT) magnetic tunnel junction of a STT-MRAM device. The STT-MRAM device is composed of a second reference layer, a second tunnel barrier layer, and a second free layer where the STT magnetic tunnel junction has a smaller cross-sectional area than the VCMA magnetic tunnel junction (MTJ).

Abstract: The present disclosure is drawn to, among other things, a configuration bit including at least four resistive elements and a voltage amplifier. At least two first resistive elements may be electrically connected in series via a first electrode and at least two second resistive elements may be electrically connected in series via a second electrode. The at least two first resistive elements may be electrically connected in parallel to the at least two second resistive elements via a third electrode and a fourth electrode. The first electrode and the second electrode may be electrically connected to a voltage supply. The third electrode and the fourth electrode may be electrically connected to an input of the voltage amplifier.

Abstract: The present disclosure is drawn to, among other things, a device comprising input circuitry; weight operation circuitry electrically connected to the input circuitry; bias operation circuitry electrically connected to the weight operation circuitry; storage circuitry electrically connected to the weight operation circuitry and the bias operation circuitry; and activation function circuitry electrically connected to the bias operation circuitry, wherein at least the weight operation circuitry, the bias operation circuitry, and the storage circuitry are located on a same chip.

Abstract: A semiconductor device including a magnetic tunnel junction (MTJ) stack, a first metal line above the MTJ stack and a magnetoelectric material layer above the first metal line. A semiconductor device including an array of magnetic tunnel junction (MTJ) stacks, a first metal line connected physically and electrically to a top electrode of each MTJ stack in a row of the array of MTJ stacks and a magnetoelectric material layer above the first metal line, connected physically and electrically to the first metal line. A method including forming an array of magnetic tunnel junction (MTJ) stacks, forming a first metal line above a row of the array of MTJ stacks, and forming a magnetoelectric material layer above the first metal line, connected physically and electrically to the first metal line.

Abstract: A memory system may include a magnetic tunnel junction stack, a first high resistance tunnel barrier, and a first voltage controlled magnetic anisotropy write layer. The first voltage controlled magnetic anisotropy write layer may be adjacent the high resistance tunnel barrier, and the voltage controlled magnetic anisotropy write line may include a magnetic material in direct contact with a high resistance tunnel barrier.

Abstract: A device includes a Magnetic Tunnel Junction (MTJ) memory element comprising, a reference layer, a free layer, and a magnetic tunneling layer between the reference layer and the free layer; and a pair of magneto-electric controlling layers, which have in-plane uniaxial anisotropy, wherein the pair of magneto-electric controlling layers are disposed below the free layer.

Abstract: A method for compensating for external magnetic fields in memory devices that includes positioning at least one external magnetic field sensing element adjacent to at least one array of memory cells, wherein a write driver is in electrical communication with at least one external magnetic field sensing element and at least one array of memory cells. The at least one external magnetic field sensing element is monitored for signals indicative of the present of an external magnetic field. The write current to the at least one array of memory cells can be adjusted by trimming the write driver to operate the memory device while compensating for the external magnetic field.

Abstract: A device includes a plurality of magnetic random-access memory (MRAM) cells in a first region of the device; and a dummy MRAM pillar disposed in a second region of the device, wherein the dummy MRAM pillar is not connected to an active metal feature.

Abstract: A second BEOL layer including a via dielectric layer surrounding a via including an upper metal stud and a lower metal stud separated by a liner, and a magnetic tunnel junction (MTJ) stack aligned above the via. A first back end of line (BEOL) layer including a BEOL dielectric layer surrounding a BEOL metal layer, a second BEOL layer including a via dielectric layer surrounding a via including an upper metal stud and a lower metal stud separated by a liner, a magnetic tunnel junction (MTJ) stack aligned above the via. Forming a via dielectric layer as a second back end of line (BEOL) layer, an opening, a lower metal stud in the opening, a liner on the lower metal stud and on exposed side surfaces of the opening, an upper metal stud in remaining portions of the opening, and forming a magnetic tunnel junction (MTJ) stack aligned above.