Abstract: An apparatus for generating a magnetic field including permanent magnets arranged in a plane, each magnet being spatially separated along the plane from the adjacent magnet by a predetermined spacing, each magnet having a magnetic polarity opposed to the polarity of the adjacent magnet such that a magnetic field of adjacent magnets is oriented substantially perpendicular to the plane and in opposite directions, each magnet being spatially separated in the plane from the adjacent magnet by a nonmagnetic material. A method for programming a magnetic device or sensor device using the apparatus is also described.

Abstract: An apparatus for generating a magnetic field including permanent magnets arranged in a plane, each magnet being spatially separated along the plane from the adjacent magnet by a predetermined spacing, each magnet having a magnetic polarity opposed to the polarity of the adjacent magnet such that a magnetic field of adjacent magnets is oriented substantially perpendicular to the plane and in opposite directions, each magnet being spatially separated in the plane from the adjacent magnet by a nonmagnetic material. A method for programming a magnetic device or sensor device using the apparatus is also described.

Abstract: A device has a flexible substrate supporting an array of magnetic sensors exposed to a uniform external magnetic field. One or more controllers receive magnetic sensor signals from the magnetic sensors. The one or more controllers collect reference magnetic sensor signals when the flexible substrate is aligned with the uniform external magnetic field. The one or more controllers collect first polarity magnetic sensor signals in response to deformation of the flexible substrate in a first direction. The one or more controllers collect second polarity magnetic sensor signals in response to deformation of the flexible substrate in a second direction. The magnetic sensor signals establish a profile of the orientation of the flexible substrate with respect to the uniform external magnetic field.

Abstract: A magnetic random access memory (MRAM) cell including a magnetic tunnel junction containing: a storage layer including at least one storage ferromagnetic layer, each storage ferromagnetic layer having a storage magnetization; an antiferromagnetic storage layer pinning the storage magnetization at a low threshold temperature and freeing them at a high temperature threshold; a reference layer; and a tunnel barrier layer between the reference layer and the storage layer. The magnetic tunnel junction also includes a free ferromagnetic layer having a free magnetization adapted to induce a magnetic stray field magnetically coupling the free ferromagnetic layer with the storage layer; such that the storage magnetization can be switched by the magnetic stray field when the magnetic tunnel junction is at the high temperature threshold. The disclosed MRAM cell has low power consumption.

Abstract: A mechanism is provided for a thermally assisted magnetoresistive random access memory device (TAS-MRAM) with reduced power for reading and writing. A tunnel barrier is disposed adjacent to a ferromagnetic sense layer and a ferromagnetic storage layer, such that the tunnel barrier is sandwiched between the ferromagnetic sense layer and the ferromagnetic storage layer. An antiferromagnetic pinning layer is disposed adjacent to the ferromagnetic storage layer. The pinning layer pins a magnetic moment of the storage layer until heating is applied. The storage layer includes a non-magnetic material to reduce a storage layer magnetization as compared to not having the non-magnetic material. The sense layer includes the non-magnetic material to reduce a sense layer magnetization as compared to not having the non-magnetic material.

Abstract: A thermally assisted switching MRAM element including a magnetic tunnel junction including a reference layer having a reference magnetization; a storage layer having a storage magnetization; a tunnel barrier layer included between the storage layer and the reference layer; and a storage antiferromagnetic layer exchange-coupling the storage layer such as to pin the storage magnetization at a low temperature threshold and to free it at a high temperature threshold. The antiferromagnetic layer includes: at least one first antiferromagnetic layer having a first storage blocking temperature, and at least one second antiferromagnetic layer having a second storage blocking temperature; wherein the first storage blocking temperature is below 200° C. and the second storage blocking temperature is above 250° C. The MRAM element combines better data retention compared with known MRAM elements with low writing mode operating temperature.

Abstract: A device has a flexible substrate supporting an array of magnetic sensors exposed to a uniform external magnetic field. One or more controllers receive magnetic sensor signals from the magnetic sensors. The one or more controllers collect reference magnetic sensor signals when the flexible substrate is aligned with the uniform external magnetic field. The one or more controllers collect first polarity magnetic sensor signals in response to deformation of the flexible substrate in a first direction. The one or more controllers collect second polarity magnetic sensor signals in response to deformation of the flexible substrate in a second direction. The magnetic sensor signals establish a profile of the orientation of the flexible substrate with respect to the uniform external magnetic field.

Abstract: A magnetic random access memory (MRAM) cell including a magnetic tunnel junction containing: a storage layer including at least one storage ferromagnetic layer, each storage ferromagnetic layer having a storage magnetization; an antiferromagnetic storage layer pinning the storage magnetization at a low threshold temperature and freeing them at a high temperature threshold; a reference layer; and a tunnel barrier layer between the reference layer and the storage layer. The magnetic tunnel junction also includes a free ferromagnetic layer having a free magnetization adapted to induce a magnetic stray field magnetically coupling the free ferromagnetic layer with the storage layer; such that the storage magnetization can be switched by the magnetic stray field when the magnetic tunnel junction is at the high temperature threshold. The disclosed MRAM cell has low power consumption.

Abstract: MRAM cell comprising a magnetic tunnel junction comprising a storage layer having a net storage magnetization being adjustable when the magnetic tunnel junction is at a high temperature threshold and being pinned at a low temperature threshold; a sense layer having a reversible sense magnetization; and a tunnel barrier layer between the sense and storage layers; at least one of the storage and sense layer comprising a ferrimagnetic 3d-4f amorphous alloy material comprising a sub-lattice of 3d transition metals atoms providing a first magnetization and a sub-lattice of 4f rare-earth atoms providing a second magnetization, such that at a compensation temperature of said at least one of the storage layer and the sense layer, the first magnetization and the second magnetization are substantially equal. The disclosed MRAM cell can be written and read using a small writing and reading field, respectively.

Abstract: A mechanism is provided for a thermally assisted magnetoresistive random access memory device (TAS-MRAM) with reduced power for reading and writing. A tunnel barrier is disposed adjacent to a ferromagnetic sense layer and a ferromagnetic storage layer, such that the tunnel barrier is sandwiched between the ferromagnetic sense layer and the ferromagnetic storage layer. An antiferromagnetic pinning layer is disposed adjacent to the ferromagnetic storage layer. The pinning layer pins a magnetic moment of the storage layer until heating is applied. The storage layer includes a non-magnetic material to reduce a storage layer magnetization as compared to not having the non-magnetic material. The sense layer includes the non-magnetic material to reduce a sense layer magnetization as compared to not having the non-magnetic material.

Abstract: A thermally assisted switching MRAM element including a magnetic tunnel junction including a reference layer having a reference magnetization; a storage layer having a storage magnetization; a tunnel barrier layer included between the storage layer and the reference layer; and a storage antiferromagnetic layer exchange-coupling the storage layer such as to pin the storage magnetization at a low temperature threshold and to free it at a high temperature threshold. The antiferromagnetic layer includes: at least one first antiferromagnetic layer having a first storage blocking temperature, and at least one second antiferromagnetic layer having a second storage blocking temperature; wherein the first storage blocking temperature is below 200° C. and the second storage blocking temperature is above 250° C. The MRAM element combines better data retention compared with known MRAM elements with low writing mode operating temperature.

Abstract: The present disclosure concerns a self-referenced magnetic random access memory-based ternary content addressable memory (MRAM-based TCAM) cell comprising a first and second magnetic tunnel junction; a first and second conducting strap adapted to pass a heating current in the first and second magnetic tunnel junction, respectively; a conductive line electrically connecting the first and second magnetic tunnel junctions in series; a first current line for passing a first field current to selectively write a first write data to the first magnetic tunnel junction; and a second current line for passing a write current to selectively write a second write data to the second magnetic tunnel junction, such that three distinct cell logic states can be written in the MRAM-based TCAM cell.

Abstract: The present disclosure concerns a self-referenced MRAM element, comprising a magnetic tunnel junction having a magnetoresistance, comprising: a storage layer having a storage magnetization that is pinned along a first direction when the magnetic tunnel junction is at a low temperature threshold; a sense layer having a sense magnetization; and a tunnel barrier layer included between the storage layer and the sense layer; and an aligning device arranged for providing the sense magnetization with a magnetic anisotropy along a second direction that is substantially perpendicular to the first direction such that the sense magnetization is adjusted about the second direction; the aligning device being further arranged such that, when a first read magnetic field is provided, a resistance variation range of the magnetic tunnel junction is at least about 20% of the magnetoresistance. The self-referenced MRAM cell can be read with an increased reliability and has reducing power consumption.

Abstract: The present disclosure concerns a MRAM element comprising a magnetic tunnel junction comprising: a storage layer, a sense layer, and a tunnel barrier layer included between the storage layer and the sense layer; the storage layer comprising a first magnetic layer having a first storage magnetization; a second magnetic layer having a second storage magnetization; and a non-magnetic coupling layer separating the first and second magnetic layers such that the first storage magnetization is substantially antiparallel to the second storage magnetization; the first and second magnetic layers being arranged such that: at a read temperature the first storage magnetization is substantially equal to the second storage magnetization; and at a write temperature which is higher than the read temperature the second storage magnetization is larger than the first storage magnetization. The disclosed MRAM element generates a low stray field when the magnetic tunnel junction is cooled at a low temperature.

Abstract: A magnetic random access memory (“MRAM”) cell includes: (1) a first magnetic layer having a first magnetization direction and a magnetic anisotropy axis; (2) a second magnetic layer having a second magnetization direction; and (3) a spacer layer disposed between the first magnetic layer and the second magnetic layer. The MRAM cell also includes a field line magnetically coupled to the MRAM cell and configured to induce a write magnetic field along a magnetic field axis, and the magnetic anisotropy axis is tilted relative to the magnetic field axis. During a write operation, the first magnetization direction is switchable between m directions to store data corresponding to one of m logic states, with m>2, at least one of the m directions is aligned relative to the magnetic anisotropy axis, and at least another one of the m directions is aligned relative to the magnetic field axis.

Abstract: The present disclosure concerns a magnetic random access memory MRAM cell comprising a tunnel magnetic junction formed from a first ferromagnetic layer, a second ferromagnetic layer having a second magnetization that can be oriented relative to an anisotropy axis of the second ferromagnetic layer at a predetermined high temperature threshold, and a tunnel barrier; a first current line extending along a first direction and in communication with the magnetic tunnel junction; the first current line being configured to provide an magnetic field for orienting the second magnetization when carrying a field current; wherein the MRAM cell is configured with respect to the first current line such that when providing the magnetic field, at least a component of the magnetic field is substantially perpendicular to said anisotropy axis. The MRAM cell has an improved switching efficiency, lower power consumption and improved dispersion of the switching field compared to conventional MRAM cells.

Abstract: Method for writing and reading more than two data bits to a MRAM cell comprising a magnetic tunnel junction formed from a read magnetic layer having a read magnetization, and a storage layer comprising a first storage ferromagnetic layer having a first storage magnetization, a second storage ferromagnetic layer having a second storage magnetization; the method comprising: heating the magnetic tunnel junction above a high temperature threshold; and orienting the first storage magnetization at an angle with respect to the second storage magnetization such that the magnetic tunnel junction reaches a resistance state level determined by the orientation of the first storage magnetization relative to that of the read magnetization. The method allows for storing at least four distinct state levels in the MRAM cell using only one current line to generate a writing field.

Abstract: The present disclosure concerns a magnetic random access memory MRAM cell comprising a tunnel magnetic junction formed from a first ferromagnetic layer, a second ferromagnetic layer having a second magnetization that can be oriented relative to an anisotropy axis of the second ferromagnetic layer at a predetermined high temperature threshold, and a tunnel barrier; a first current line extending along a first direction and in communication with the magnetic tunnel junction; the first current line being configured to provide an magnetic field for orienting the second magnetization when carrying a field current; wherein the MRAM cell is configured with respect to the first current line such that when providing the magnetic field, at least a component of the magnetic field is substantially perpendicular to said anisotropy axis. The MRAM cell has an improved switching efficiency, lower power consumption and improved dispersion of the switching field compared to conventional MRAM cells.

Abstract: A magnetic random access memory (“MRAM”) cell includes: (1) a first magnetic layer having a first magnetization direction and a magnetic anisotropy axis; (2) a second magnetic layer having a second magnetization direction; and (3) a spacer layer disposed between the first magnetic layer and the second magnetic layer. The MRAM cell also includes a field line magnetically coupled to the MRAM cell and configured to induce a write magnetic field along a magnetic field axis, and the magnetic anisotropy axis is tilted relative to the magnetic field axis. During a write operation, the first magnetization direction is switchable between m directions to store data corresponding to one of m logic states, with m>2, at least one of the m directions is aligned relative to the magnetic anisotropy axis, and at least another one of the m directions is aligned relative to the magnetic field axis.

Abstract: Method for writing and reading more than two data bits to a MRAM cell comprising a magnetic tunnel junction formed from a read magnetic layer having a read magnetization, and a storage layer comprising a first storage ferromagnetic layer having a first storage magnetization, a second storage ferromagnetic layer having a second storage magnetization; the method comprising: heating the magnetic tunnel junction above a high temperature threshold; and orienting the first storage magnetization at an angle with respect to the second storage magnetization such that the magnetic tunnel junction reaches a resistance state level determined by the orientation of the first storage magnetization relative to that of the read magnetization. The method allows for storing at least four distinct state levels in the MRAM cell using only one current line to generate a writing field.