Patent application number | Description | Published |
20080304353 | MEMORY STORAGE DEVICE WITH HEATING ELEMENT - A memory storage device is provided that includes a storage cell having a changeable magnetic region. The changeable magnetic region includes a material having a magnetization state that is responsive to a change in temperature. The memory storage device also includes a heating element. The heating element is proximate to the storage cell for selectively changing the temperature of the changeable magnetic region of said storage cell. By heating the storage cell via the heating element, as opposed to heating the storage cell by directly applying current thereto, more flexibility is provided in the manufacture of the storage cells. | 12-11-2008 |
20090207653 | MEMORY STORAGE DEVICE WITH HEATING ELEMENT - A memory storage device is provided that includes a storage cell having a changeable magnetic region. The changeable magnetic region includes a material having a magnetization state that is responsive to a change in temperature. The memory storage device also includes a heating element. The heating element is proximate to the storage cell for selectively changing the temperature of the changeable magnetic region of said storage cell. By heating the storage cell via the heating element, as opposed to heating the storage cell by directly applying current thereto, more flexibility is provided in the manufacture of the storage cells. | 08-20-2009 |
20090237982 | Magnetically De-Coupling Magnetic Tunnel Junctions and Bit/Word Lines for Reducing Bit Selection Errors in Spin-Momentum Transfer Switching - Techniques for shielding magnetic memory cells from magnetic fields are presented. In accordance with aspects of the invention, a magnetic storage element is formed with at least one conductive segment electrically coupled to the magnetic storage element. At least a portion of the conductive segment is surrounded with a magnetic liner. The magnetic liner is operative to divert at least a portion of a magnetic field created by a current passing through the conductive segment away from the magnetic storage element. | 09-24-2009 |
20120241878 | MAGNETIC TUNNEL JUNCTION WITH IRON DUSTING LAYER BETWEEN FREE LAYER AND TUNNEL BARRIER - A magnetic tunnel junction (MTJ) for a magnetic random access memory (MRAM) includes a magnetic free layer having a variable magnetization direction; an iron (Fe) dusting layer formed on the free layer; an insulating tunnel barrier formed on the dusting layer; and a magnetic fixed layer having an invariable magnetization direction, disposed adjacent the tunnel barrier such that the tunnel barrier is located between the free layer and the fixed layer; wherein the free layer and the fixed layer have perpendicular magnetic anisotropy and are magnetically coupled through the tunnel barrier. | 09-27-2012 |
20130005051 | MAGNETIC STACKS WITH PERPENDICULAR MAGNETIC ANISOTROPY FOR SPIN MOMENTUM TRANSFER MAGNETORESISTIVE RANDOM ACCESS MEMORY - A magnetic tunnel junction (MTJ) includes a magnetic free layer, having a variable magnetization direction; an insulating tunnel barrier located adjacent to the free layer; a magnetic fixed layer having an invariable magnetization direction, the fixed layer disposed adjacent the tunnel barrier such that the tunnel barrier is located between the free layer and the fixed layer, wherein the free layer and the fixed layer have perpendicular magnetic anisotropy; and one or more of: a composite fixed layer, the composite fixed layer comprising a dusting layer, a spacer layer, and a reference layer; a synthetic antiferromagnetic (SAF) fixed layer structure, the SAF fixed layer structure comprising a SAF spacer located between the fixed layer and a second fixed magnetic layer; and a dipole layer, wherein the free layer is located between the dipole layer and the tunnel barrier. | 01-03-2013 |
20130005052 | MAGNETIC TUNNEL JUNCTION WITH IRON DUSTING LAYER BETWEEN FREE LAYER AND TUNNEL BARRIER - A magnetic tunnel junction (MTJ) for a magnetic random access memory (MRAM) includes a magnetic free layer having a variable magnetization direction; an iron (Fe) dusting layer formed on the free layer; an insulating tunnel barrier formed on the dusting layer; and a magnetic fixed layer having an invariable magnetization direction, disposed adjacent the tunnel barrier such that the tunnel barrier is located between the free layer and the fixed layer; wherein the free layer and the fixed layer have perpendicular magnetic anisotropy and are magnetically coupled through the tunnel barrier. | 01-03-2013 |
20140151620 | SELF-ALIGNED WIRE FOR SPINTRONIC DEVICE - A method for fabricating a spintronic cell includes forming a cavity in a substrate, forming a wire in the cavity, depositing a spacer layer over exposed portions of the substrate and the conductive field line, depositing a layer of conductive material on a portion of the spacer layer, removing portions of the layer of conductive material to define a conductive strap portion, wherein the conductive strap portion has a first distal region a second distal region and a medial region arranged therebetween, wherein the medial region has a cross sectional area that is less than a cross sectional area of the first distal region and a cross sectional area of the second distal region, and forming an spintronic device stack on the conductive strap portion above the conductive field line. | 06-05-2014 |
20140151824 | SELF-ALIGNED WIRE FOR SPINTRONIC DEVICE - A method for fabricating a spintronic cell includes forming a cavity in a substrate, forming a wire in the cavity, depositing a spacer layer over exposed portions of the substrate and the conductive field line, depositing a layer of conductive material on a portion of the spacer layer, removing portions of the layer of conductive material to define a conductive strap portion, wherein the conductive strap portion has a first distal region a second distal region and a medial region arranged therebetween, wherein the medial region has a cross sectional area that is less than a cross sectional area of the first distal region and a cross sectional area of the second distal region, and forming an spintronic device stack on the conductive strap portion above the conductive field line. | 06-05-2014 |
20140264664 | PARALLEL SHUNT PATHS IN THERMALLY ASSISTED MAGNETIC MEMORY CELLS - A thermally assisted magnetic memory cell device includes a substrate, a first electrode disposed on the substrate, a magnetic tunnel junction disposed on the first electrode, a second electrode disposed on the magnetic tunnel junction, a conductive hard mask disposed on the second electrode and a parallel shunt path coupled to the magnetic tunnel junction, thereby electrically coupling the first and second electrodes. | 09-18-2014 |
20140268987 | Thermally-Assisted Mram with Ferromagnetic Layers with Temperature Dependent Magnetization - A technique is provided for a thermally assisted magnetoresistive random access memory device. The device has a synthetic antiferromagnetic layer disposed on an antiferromagnetic layer. The synthetic antiferromagnetic layer has a first ferromagnetic storage layer, a non-magnetic coupling layer disposed on the first ferromagnetic storage layer, and a second ferromagnetic storage layer disposed on the non-magnetic coupling layer. A non-magnetic tunnel barrier is disposed on the second ferromagnetic storage layer, and a ferromagnetic sense layer is disposed on the non-magnetic tunnel barrier. A first ferromagnetic critical temperature of the first ferromagnetic storage layer is higher than an antiferromagnetic critical temperature of the antiferromagnetic layer, is higher than a second ferromagnetic critical temperature of the second ferromagnetic storage layer, and is higher than a third ferromagnetic critical temperature of the ferromagnetic sense layer. | 09-18-2014 |
20140269028 | Thermally-Assisted Mram with Ferromagnetic Layers with Temperature Dependent Magnetization - A technique is provided for a thermally assisted magnetoresistive random access memory device. The device has a synthetic antiferromagnetic layer disposed on an antiferromagnetic layer. The synthetic antiferromagnetic layer has a first ferromagnetic storage layer, a non-magnetic coupling layer disposed on the first ferromagnetic storage layer, and a second ferromagnetic storage layer disposed on the non-magnetic coupling layer. A non-magnetic tunnel barrier is disposed on the second ferromagnetic storage layer, and a ferromagnetic sense layer is disposed on the non-magnetic tunnel barrier. A first ferromagnetic critical temperature of the first ferromagnetic storage layer is higher than an antiferromagnetic critical temperature of the antiferromagnetic layer, is higher than a second ferromagnetic critical temperature of the second ferromagnetic storage layer, and is higher than a third ferromagnetic critical temperature of the ferromagnetic sense layer. | 09-18-2014 |
20140273282 | PARALLEL SHUNT PATHS IN THERMALLY ASSISTED MAGNETIC MEMORY CELLS - A thermally assisted magnetic memory cell device includes a substrate, a first electrode disposed on the substrate, a magnetic tunnel junction disposed on the first electrode, a second electrode disposed on the magnetic tunnel junction, a conductive hard mask disposed on the second electrode and a parallel shunt path coupled to the magnetic tunnel junction, thereby electrically coupling the first and second electrodes. | 09-18-2014 |
Patent application number | Description | Published |
20090261820 | WAFER FOR ELECTRICALLY CHARACTERIZING TUNNEL JUNCTION FILM STACKS WITH LITTLE OR NO PROCESSING - Probes are electrically connected to a surface of a tunnel junction film stack comprising a free layer, a tunnel barrier, and a pinned layer. Resistances are determined for a variety of probe spacings and for a number of magnetizations of one of the layers of the stack. The probe spacings are a distance from a length scale, which is related to the Resistance-Area (RA) product of the tunnel junction film stack. Spacings from as small as possible to about 40 times the length scale are used. Beneficially, the smallest spacing between probes used during a resistance measurement is under 100 microns. A measured in-plane MagnetoResistance (MR) curve is determined from the “high” and “low” resistances that occur at the two magnetizations of this layer. The RA product, resistances per square of the free and pinned layers, and perpendicular MR are determined through curve fitting. | 10-22-2009 |
20090267597 | Techniques for Electrically Characterizing Tunnel Junction Film Stacks with Little or no Processing - Probes are electrically connected to a surface of a tunnel junction film stack comprising a free layer, a tunnel barrier, and a pinned layer. Resistances are determined for a variety of probe spacings and for a number of magnetizations of one of the layers of the stack. The probe spacings are a distance from a length scale, which is related to the Resistance-Area (RA) product of the tunnel junction film stack. Spacings from as small as possible to about 40 times the length scale are used. Beneficially, the smallest spacing between probes used during a resistance measurement is under 100 microns. A measured in-plane MagnetoResistance (MR) curve is determined from the “high” and “low” resistances that occur at the two magnetizations of this layer. The RA product, resistances per square of the free and pinned layers, and perpendicular MR are determined through curve fitting. | 10-29-2009 |
20090309587 | Techniques for Electrically Characterizing Tunnel Junction Film Stacks with Little or no Processing - Probes are electrically connected to a surface of a tunnel junction film stack comprising a free layer, a tunnel barrier, and a pinned layer. Resistances are determined for a variety of probe spacings and for a number of magnetizations of one of the layers of the stack. The probe spacings are a distance from a length scale, which is related to the Resistance-Area (RA) product of the tunnel junction film stack. Spacings from as small as possible to about 40 times the length scale are used. Beneficially, the smallest spacing between probes used during a resistance measurement is under 100 microns. A measured in-plane MagnetoResistance (MR) curve is determined from the “high” and “low” resistances that occur at the two magnetizations of this layer. The RA product, resistances per square of the free and pinned layers, and perpendicular MR are determined through curve fitting. | 12-17-2009 |
20100023287 | Techniques for Electrically Characterizing Tunnel Junction Film Stacks with Little or no Processing - Probes are electrically connected to a surface of a tunnel junction film stack comprising a free layer, a tunnel barrier, and a pinned layer. Resistances are determined for a variety of probe spacings and for a number of magnetizations of one of the layers of the stack. The probe spacings are a distance from a length scale, which is related to the Resistance-Area (RA) product of the tunnel junction film stack. Spacings from as small as possible to about 40 times the length scale are used. Beneficially, the smallest spacing between probes used during a resistance measurement is under 100 microns. A measured in-plane MagnetoResistance (MR) curve is determined from the “high” and “low” resistances that occur at the two magnetizations of this layer. The RA product, resistances per square of the free and pinned layers, and perpendicular MR are determined through curve fitting. | 01-28-2010 |
20100085793 | Wall Nucleation Propagation for Racetrack Memory - A shift register is provided, the shift register comprising at least one track including a storage region. The storage region comprises a plurality of magnetic domains for storing data. A given first one of the plurality of magnetic domains is adjacent to a given second one of the plurality of magnetic domains. The given first one of the plurality of magnetic domains and the given second one of the plurality of magnetic domains are arranged in a linear configuration. Further, the given first one of the plurality of magnetic domains and the given second one of the plurality of magnetic domains are separated from one another by at least one layer of non-magnetic material. The at least one layer of non-magnetic material preventing a propagation of a nucleated wall from traveling between the given first one of the plurality of magnetic domains and the given second one of the plurality of magnetic domains. The shift register is configured such that an electric current applied to the track is operative to shift data stored within at least one of the plurality of magnetic domains of the storage region, along the track, in a direction of the electric current. The data stored within the at least one of the plurality of magnetic domains is shifted as a function of the direction of the electric current. | 04-08-2010 |
20110039020 | Magnetic Materials Having Superparamagnetic Particles - Magnetic materials and uses thereof are provided. In one aspect, a magnetic film is provided. The magnetic film comprises superparamagnetic particles on at least one surface thereof. The magnetic film may be patterned and may comprise a ferromagnetic material. The superparamagnetic particles may be coated with a non-magnetic polymer and/or embedded in a non-magnetic host material. The magnetic film may have increased damping and/or decreased coercivity. | 02-17-2011 |