Abstract: A mechanism is provided for a spin torque transfer random access memory device. A tunnel barrier is disposed on a reference layer, and a free layer is disposed on the tunnel barrier. The free layer includes an iron layer as a top part of the free layer. A metal oxide layer is disposed on the iron layer, and a cap layer is disposed on the metal oxide layer.

Abstract: A ferromagnetic tunnel junction structure comprising a first ferromagnetic layer, a second ferromagnetic layer, and a tunnel barrier layer that is interposed between the first ferromagnetic layer and the second ferromagnetic layer, wherein the tunnel barrier layer includes a crystalline non-magnetic material having constituent elements that are similar to those of an crystalline oxide that has spinel structure as a stable phase structure; the non-magnetic material has a cubic structure having a symmetry of space group Fm-3m or F-43m in which atomic arrangement in the spinel structure is disordered; and an effective lattice constant of the cubic structure is substantially half of the lattice constant of the oxide of the spinel structure.

Abstract: A method or manufacturing an integrated circuit structure with a magnetoresistance component is provided. A substrate is provided. A circuit structure layer including a metal pad is formed on the substrate. A dielectric layer is formed on the circuit structure. A metal damascene structure is formed in the dielectric layer. An opening is formed in the dielectric layer so as to form a step-drop. A magnetoresistance material layer is formed on the dielectric layer after forming the metal damascene structure and the opening. A photolithography process is applied to pattern the magnetoresistance material layer to form a magnetoresistance component electrically connected to the metal damascene structure.

Abstract: A method of manufacturing a magnetoresistive-based device having magnetic material layers formed between a first electrically conductive layer and a second electrically conductive layer, the magnetic materials layers including a tunnel barrier layer formed between a first magnetic materials layer and a second magnetic materials layer, including removing the first electrically conductive layer and the first magnetic materials layer unprotected by a first hard mask, to form a first electrode and a first magnetic materials, respectively; and removing the tunnel barrier layer, second magnetic materials layer, and second electrically conductive layer unprotected by the second hard mask to form a tunnel barrier, second magnetic materials, and a second electrode.

Abstract: A tunneling magnetoresistive sensor has an extended pinned layer wherein both the MgO spacer layer and the underlying ferromagnetic pinned layer extend beyond the back edge of the ferromagnetic free layer in the stripe height direction and optionally also beyond the side edges of the free layer in the trackwidth direction. A patterned photoresist layer with a back edge is formed on the sensor stack and a methanol (CH3OH)-based reactive ion etching (RIE) removes the unprotected free layer, defining the free layer back edge. The methanol-based RIE terminates at the MgO spacer layer without damaging the underlying reference layer. A second patterned photoresist layer may be deposited and a second methanol-based RIE may be performed if it is desired to have the reference layer also extend beyond the side edges of the free layer in the trackwidth direction.

Abstract: Vertical meander inductors for small core voltage regulators and approaches to fabricating vertical meander inductors for small core voltage regulators are described. For example, a semiconductor die includes a substrate. An integrated circuit is disposed on an active surface of the substrate. An inductor is coupled to the integrated circuit. The inductor is disposed conformal with an insulating layer disposed on an essentially planar surface of the substrate. The insulating layer has an undulating topography.

Abstract: A semiconductor device includes: a spin torque written in-plane magnetization magnetoresistive element, placed over the main surface of a semiconductor substrate, whose magnetization state can be changed according to the direction of a current flow; and a first wiring electrically coupled with the magnetoresistive element and extended toward the direction along the main surface. The aspect ratio of the magnetoresistive element as viewed in a plane is a value other than 1. In a memory cell area where multiple memory cells in which the magnetoresistive element and a switching element are electrically coupled with each other are arranged, the following measure is taken: multiple magnetoresistive elements adjoining to each other in the direction of length of each magnetoresistive element as viewed in a plane are so arranged that they are not on an identical straight line extended in the direction of length.

Abstract: A semiconductor device includes a magnetic tunnel junction (MTJ) storage element configured to be disposed in a common interlayer metal dielectric (IMD) layer with a logic element. Cap layers separate the common IMD layer from a top and bottom IMD layer. Top and bottom electrodes are coupled to the MTJ storage element. Metal connections to the electrodes are formed in the top and bottom IMD layers respectively through vias in the separating cap layers. Alternatively, the separating cap layers are recessed and the bottom electrodes are embedded, such that direct contact to metal connections in the bottom IMD layer is established. Metal connections to the top electrode in the common IMD layer are enabled by isolating the metal connections from the MTJ storage elements with metal islands and isolating caps.

Abstract: A memory device may comprise a magnetic tunnel junction (MTJ) stack, a bottom electrode (BE) layer, and a contact layer. The MTJ stack may include a free layer, a barrier, and a pinned layer. The BE layer may be coupled to the MTJ stack, and encapsulated in a planarized layer. The BE layer may also have a substantial common axis with the MTJ stack. The contact layer may be embedded in the BE layer, and form an interface between the BE layer and the MTJ stack.

Abstract: The present invention relates to a circuit protection device and a method of manufacturing the same. The circuit protection device includes a common mode noise filter having a plurality of sheets, each of the sheets being formed to optionally include a coil pattern, an internal electrode, a hole filled with a conductive material, and a hole filled with a magnetic material; and an electrostatic discharge (ESD) protection device having a plurality of sheets, each of the sheets being formed to optionally include an internal electrode and a hole filled with an ESD protection material.

Abstract: Perpendicular spin transfer torque memory (STTM) devices with enhanced stability and methods of fabricating perpendicular STTM devices with enhanced stability are described. For example, a material layer stack for a magnetic tunneling junction includes a fixed magnetic layer. A dielectric layer is disposed above the fixed magnetic layer. A free magnetic layer is disposed above the dielectric layer. A conductive oxide material layer is disposed on the free magnetic layer.

Abstract: A method of forming a semiconductor device includes forming a perpendicular magnetized magnetic device, annealing the perpendicular magnetized magnetic device, and applying a magnetic field to the perpendicular magnetized magnetic device. The semiconductor device may be a magnetoresistance data storage device. The magnetic field is applied in a direction that is substantially perpendicular to a substrate coupled to the perpendicular magnetized magnetic device.

Abstract: A magnetic thin film deposition having PMA (perpendicular magnetic anisotropy) is a multilayered fabrication of materials having differing crystal symmetries that smoothly transition by use of a seed layer that promotes symmetry matching. An interface between layers in the deposition, such as an interface between a layer of MgO and an Fe-containing ferromagnetic layer, is a source of perpendicular magnetic anisotropy which then propagates throughout the remainder of the deposition by means of the symmetry matching seed layer.

Abstract: A synthetic antiferromagnet serving as a reference layer for a magnetic tunnel junction is a laminate with a plurality of “x+1” magnetic sub-layers and “x” non-magnetic spacers arranged in an alternating fashion, with a magnetic sub-layer at the top and bottom of the laminated stack. Each spacer has a top and bottom surfaces that interface with adjoining magnetic sub-layers generating antiferromagnetic coupling between the adjoining sub-layers. Perpendicular magnetic anisotropy is induced in each magnetic sub-layer through an interface with a spacer. Thus the dipole field exerted on a free layer is substantially reduced compared with that produced by a conventional synthetic antiferromagnetic reference layer. Magnetic sub-layers are preferably Co while Ru, Rh, or Ir may serve as non-magnetic spacers.

Abstract: A method to make magnetic random access memory (MRAM), or integrated device in general, is provided. Oxygen ion implantation is used to convert the photolithography exposed areas into metal oxide dielectric matrix. To confine the oxygen ions within the desired region, heavy metals with large atomic number, such as Hf, Ta, W, Re, Os, Ir, Pt, Au is used as ion mask and bottom ion-stopping layer. An oxygen gettering material, selected from Mg, Zr, Y, Th, Ti, Al, Ba is added above and below the active device region to effectively capture the impinging oxygen. After a high temperature anneal, a buried metal oxide layer with sharp oxygen boundaries across the active device region can be obtained.

Abstract: A MEMS gyro is provided, having a movable portion, a non-movable portion, and a magnetic sensing structure that comprises a magnetic source disposed at the movable portion, a magnetic sensing element positioned at the non-movable portion. The movable portion is capable of moving in response to external angular velocity or an external accelerator such that the magnetic field sensed by the magnetic sensing element is in relation to the movement of the movable portion, therefore, the angular velocity or the accelerator. A method of making the MEMS gyro device is disclosed herein.

Abstract: Methods of forming material junctions for magnetic memory devices are described. The methods involve providing a material stack including a bottom magnetic tunneling junction layer, a tunneling barrier layer, and a top magnetic tunneling junction layer (from bottom to top) on a substrate. The top magnetic tunneling junction layer is patterned to form a top magnetic tunneling junction and then a dielectric spacer layer may be formed over the top magnetic tunneling junction. The dielectric spacer is etched to leave a vertical dielectric spacer to maintain electrical separation between the top magnetic tunneling junction and the bottom magnetic tunneling junction during and following subsequent etching/processing. In an alternative embodiment the spacer layer is lithographically defined.

Abstract: A method is provided for fabricating a transistor. The method includes providing a semiconductor substrate; and configuring a channel region along a first direction. The method also includes forming trenches at both sides of the channel region along a second direction; and forming a magnetic material layer in each of the trenches. Further, the method includes magnetizing the magnetic material layers to form a magnetic field in the channel region between adjacent magnetic material layers; and forming source/drain regions at both ends of the channel region along the first direction.

Abstract: In some embodiments, HPC techniques are applied to the screening and evaluating the materials, process parameters, process sequences, and post deposition treatment processes for the development of STT-RAM stacks. Simple test structures are employed for initial screening of basic materials properties of candidate materials for each layer within the stack. The use of multiple site-isolated regions on a single substrate allows many material and/or process conditions to be evaluated in a timely and cost effective manner. Interactions between the layers as well as interactions with the substrate can be investigated in a straightforward manner.

Abstract: Circuits and methods use a feedback arrangement to select one or more measuring devices from a plurality of measuring devices in order to rapidly identify a direction of a sensed parameter. In some embodiments, the plurality of measuring devices corresponds to a plurality of magnetic field sensing elements and the sensed parameter is a magnetic field.

Abstract: A spin filter includes a first electrode configured to be formed with a zigzag graphene ribbon with an even number of rows extending in a first direction, and to have a magnetic moment in a second direction crossing with the first direction; a second electrode configured to be formed with a zigzag graphene ribbon with an even number of rows extending in the first direction, and to have a magnetic moment in the second direction; and a channel region configured to be placed between the first electrode and the second electrode, and to have an energy level allowing up-spin electrons or down-spin electrons to pass.

Abstract: A spintronic electronic apparatus having a multilayer structure. The apparatus includes a substrate, having disposed in succession upon the substrate; a bottom interface layer; a pinned layer; a tunneling barrier; a free layer; and a top interface layer, wherein the apparatus operates as a non-resonant magnetic tunnel junction in a large amplitude, out-of-plane magnetization precession regime having weakly current dependent, large diode volt-watt sensitivity when external microwave signals that exceed a predetermined threshold current and have a frequency that is lower than a predetermined level excite the magnetization precession.

Abstract: The present disclosure relates to a magnetic tunnel junction (MTJ) device and its fabricating method. Through forming MTJ through a damascene process, device damage due to the etching process and may be avoided. In some embodiments, a spacer is formed between a first portion and a second portion of the MTJ to prevent the tunnel insulating layer of the MTJ from being damaged in subsequent processes, greatly increasing product yield thereby. In other embodiments, signal quality may be improved and magnetic flux leakage may be reduced through the improved cup-shaped MTJ structure of this invention.

Abstract: A manufacturing method of a magnetic recording medium includes steps of forming a magnetic recording layer, a first mask layer, a second mask layer containing silicon as primary component, a strip layer, a third mask layer, and a resist layer, a step of patterning the resist layer to provide a pattern, steps of transferring the pattern to the third mask layer, to the strip layer, and to the second mask layer, a step of removing the strip layer by wet etching and of stripping the third mask layer and the resist layer above the magnetic recording layer, steps of transferring the pattern to the first mask layer and to the magnetic recording layer, and a step of stripping the first mask layer remaining on the magnetic recording layer.

Abstract: This invention comprises a method to make small MTJ element using hybrid etching and oxygen plasma immersion ion implantation. The method has no removal of the magnetic free layer (or memory layer) and hence prevents any possible physical damage near the free layer edges. After photolithography patterning, alternative Ta, Ru, Ta etchings are performed before it stops on an MgO intermediate layer above the free layer. Then an oxygen plasma immersion ion implantation is performed to completely oxidize the exposed portion of the free layer, leaving the hard mask covered portion unchanged which define the lateral width of the MTJ element.

Abstract: A magnetic tunnel junction device includes a first electrode having a curved top surface, a magnetic tunnel junction layer formed along the top surface of the first electrode, and a second electrode formed on the magnetic tunnel junction layer.

Abstract: Memory cell comprising two conductors, with a serially connected magnetic storage element and a Schottky diode between the two conductors. The Schottky diode provides a unidirectional conductive path between the two conductors and through the element. The Schottky diode is formed between a metal layer in one of the two conductors and a processed junction layer. Methods for process and for operation of the memory cell are also disclosed. The memory cell using the Schottky diode can be designed for high speed operation and with high density of integration. Advantageously, the junction layer can also be used as a hard mask for defining the individual magnetic storage element in the memory cell. The memory cell is particularly useful for magnetic random access memory (MRAM) circuits.

Abstract: Ferroelectric capacitors (42) are formed over a semiconductor substrate (10), then, a barrier film (46) directly covering the ferroelectric capacitors (42) is formed. Thereafter, wirings (56a etc.) connected to the ferroelectric capacitors (42) are formed. Further, a barrier film (58) is formed at a position higher than the wirings (56a etc.). In forming the barrier film (46), a film stack is formed, the film stack including at least two kinds of diffusion preventive films (46a and 46b) having different components and preventing diffusion of hydrogen or water.

Abstract: A method for making a current-perpendicular-to-the-plane (CPP) magnetoresistive (MR) sensor that has a reference layer with low coercivity includes first depositing, within a vacuum chamber, a seed layer and an antiferromagnetic layer on a substrate without the application of heat. The substrate with deposited layers is then heated to between 200-600° C. for between 1 to 120 minutes. The substrate with deposited layers is then cooled, preferably to room temperature (i.e., below 50° C., but to at least below 100° C., in the vacuum chamber. After cooling of the antiferromagnetic layer, the ferromagnetic reference layer is deposited on the antiferromagnetic layer. Then the substrate with deposited layers is removed from the vacuum chamber and subjected to a second annealing, in the presence of a magnetic field, by heating to a temperature between 200-400° C. for between 0.5-50 hours.

Abstract: The present disclosure provides a method of fabricating a semiconductor device. The method includes providing a semiconductor substrate having a first region and a second region, forming a high-k dielectric layer over the semiconductor substrate, forming a capping layer over the high-k dielectric layer in the first region, forming a first metal layer over capping layer in the first region and over the high-k dielectric in the second region, thereafter, forming a first gate stack in the first region and a second gate stack in the second region, protecting the first metal layer in the first gate stack while performing a treatment process on the first metal layer in the second gate stack, and forming a second metal layer over the first metal layer in the first gate stack and over the treated first metal layer in the second gate stack.

Abstract: Embodiments of the present invention provide methods and apparatus for forming a patterned magnetic layer for use in magnetic media. According to embodiments of the present application, a silicon oxide layer formed by low temperature chemical vapor deposition is used to form a pattern in a hard mask layer, and the patterned hard mask is used to form a patterned magnetic layer by plasma ion implantation.

Abstract: A resistive memory device includes a first electrode and a first insulation layer arranged on the first electrode. A portion of the first electrode is exposed through a first hole in the first insulation layer. A first variable resistance layer contacts the exposed portion of the first electrode and extends on the first insulation layer around the first hole. A first switching device electrically connects to the first resistive switching layer.

Abstract: Provided is a method of fabricating a semiconductor device. The method of fabricating a semiconductor device includes forming a plurality of magnetic memory patterns spaced apart from each other on a substrate, with each of the magnetic memory patterns including a free pattern, a tunnel barrier pattern, and a reference pattern which are stacked on the substrate, performing a magnetic thermal treatment process on the magnetic memory patterns, and forming a passivation layer on the magnetic memory patterns. The magnetic thermal treatment process and the forming of the passivation layer are simultaneously performed in one reactor.

Abstract: A magnetoresistive device includes a substrate and an electrically insulating layer arranged over the substrate. The magnetoresistive device further includes a first free layer embedded in the electrically insulating layer and a second free layer embedded in the electrically insulating layer. The first free layer and the second free layer are separated by a portion of the electrically insulating layer.

Abstract: A method for manufacturing a semiconductor device includes accommodating in a processing chamber a semiconductor structural body having a semiconductor substrate and a laminated structure formed on the semiconductor substrate and having multiple metal films including a noble-metal film, and generating a bias voltage on the semiconductor substrate while generating an oxygen plasma in the processing chamber such that a plasma treatment removes at least part of the noble-metal film in the laminated structure of the semiconductor structural body.

Abstract: [PURPOSE] According to the invention there is provided a magneto-resistive effect element having a larger magneto-resistive ratio than in the prior art. [SOLUTION MEANS] The magneto-resistive effect element (10) of the invention has a compound semiconductor layer (11) composed of a compound semiconductor such as InAs, metal layers (12A and 12B) composed of a metal element such as Ni not composing the compound semiconductor, and interlayers (13A and 13B) of NiInAs or the like composed of the constituent elements of the compound semiconductor and a metal element, situated between the compound semiconductor layer and the metal layer. In the magneto-resistive effect element (10) of the invention, application of a magnetic field (50) alters the conductance with respect to the electric current (60) flowing through the metal layer (12B), interlayer (13B), compound semiconductor layer (11), interlayer (13A) and metal layer (12A).

Abstract: This invention comprises methods to form isolated magnetic tunneling junction (MTJ) memory element with small footprint using oxygen-ion implantation. After patterned resist is form on an MTJ film, the substrate is subject to a series of ion implantations outside the mask areas to subsequently implant Mg and oxygen ions into the exposed MTJ junction region, followed by high temperature rapid thermal annealing. Using such a process, implanted oxygen ions, Mg ions and non-oxidized Mg atoms in MTJ stack form highly resistive MgO crystalline and the ion implanted area is converted into electrically insulated metal oxide, creating a shape well-defined MTJ memory element with ultra-small dimensions and vertical edges.

Abstract: An embodiment includes a magnetic tunnel junction (MTJ) including a free magnetic layer, a fixed magnetic layer, and a tunnel barrier between the free and fixed layers; the tunnel barrier directly contacting a first side of the free layer; and an oxide layer directly contacting a second side of the free layer; wherein the tunnel barrier includes an oxide and has a first resistance-area (RA) product and the oxide layer has a second RA product that is lower than the first RA product. The MTJ may be included in a perpendicular spin torque transfer memory. The tunnel barrier and oxide layer form a memory having high stability with an RA product not substantively higher than a less table memory having a MTJ with only a single oxide layer. Other embodiments are described herein.

Abstract: According to one embodiment, a magnetic memory is disclosed. The magnetic memory includes a substrate, and a contact plug provided on the substrate. The contact plug includes a first contact plug, and a second contact plug provided on the first contact plug and having a smaller diameter than that of the first contact plug. The magnetic memory further includes a magnetoresistive element provided on the second contact plug. The diameter of the second contact plug is smaller than that of the magnetoresistive element.

Abstract: A magnetoresistive effect element includes first and second conductive layers, a first magnetic layer between the first and second conductive layers having a magnetization direction that is unchangeable, a second magnetic layer between the first and second conductive layers having a magnetization direction that is changeable, a tunnel barrier layer between the first and second magnetic layers, a nonmagnetic layer between the second magnetic layer and the second conductive layer, and a conductive sidewall film that provides a current path between the second magnetic layer and the second conductive layer that has a lower resistance than a current path through the nonmagnetic layer.

Abstract: According to one embodiment, a magnetoresistive element includes first and magnetic layers, first and second non-magnetic layers and a W layer. Each of the first and second magnetic layers includes an axis of easy magnetization in a direction perpendicular to a film plane. The first magnetic layer has a variable magnetization direction. The second magnetic layer has an invariable magnetization direction. The first non-magnetic layer is provided between the first and second magnetic layers. The second non-magnetic layer is arranged on a surface of the first magnetic layer opposite to a surface on which the first non-magnetic layer is arranged and contains MgO. The W layer is arranged on a surface of the second non-magnetic layer opposite to a surface on which the first magnetic layer is arranged, and is in contact with the surface of the second non-magnetic layer.

Abstract: An electronic device comprising a semiconductor memory unit that includes a resistance variable element formed over a substrate, and including stacked therein a bottom electrode, a variable resistance layer and a top electrode, and a barrier layer formed over the resistance variable element, and including an amorphous silicon layer which is doped with at least one kind of impurity.

Abstract: According to one embodiment, a magnetic storage device includes an insulating region, a lower electrode including a first portion formed in a hole provided in the insulating region and a second portion protruded from the insulating region, a spacer insulating film formed on a side surface of at least the second portion of the lower electrode, a magnetic tunneling junction portion formed on a top surface of the lower electrode, and an upper electrode formed on the magnetic tunneling junction portion.

Abstract: A method is provided for forming a first via with an electrically conductive material, for example, copper, that is formed over and coupled to a conductive landing pad of an MRAM array. A sputter step is performed to lower the surface of the first via below that of a surrounding dielectric material. This recess is repeated in subsequent processing steps, providing alignment marks for the formation of a magnetic tunnel junction. The magnetic tunnel junction may be offset from the first via, and a second via being formed above the magnetic tunnel junction and to a conductive layer.

Abstract: According to one embodiment, a magnetic memory including an isolation region with an insulator in a trench is disclosed. The isolation region defines active areas extending in a 1st direction and having 1st and 2nd active areas, an isolation region extending in a 2nd direction perpendicular to the 1st direction exists between the 1st and 2nd active areas. 1st and 2nd word lines extending in the 2nd direction are buried in a surface of semiconductor substrate. 1st and 2nd select transistors connected to the word lines are on the 1st active area. 1st and 2nd variable resistance elements connected to drain regions of the 1st and 2nd select transistors are on the 1st active area.

Abstract: According to one embodiment, a magnetoresistive element comprises a storage layer as a ferromagnetic layer which has magnetic anisotropy perpendicular to film planes, and in which a magnetization direction is variable, a reference layer as a ferromagnetic layer which has magnetic anisotropy perpendicular to film planes, and in which a magnetization direction is invariable, a tunnel barrier layer as a nonmagnetic layer formed between the storage layer and the reference layer, and a first underlayer formed on a side of the storage layer, which is opposite to a side facing the tunnel barrier layer, and containing amorphous W.

Abstract: The present invention discloses highly sensitive magnetic heterojunction device consisting of a composite comprising ferromagnetic (La0.66Sr0.34MnO3) LSMO layer with ultra-thin ferrimagnetic CoFe2O4 (CFO) layer capable of giant resistive switching (RS) which can be tuned at micro tesla magnetic field at room temperature.

Abstract: A method of fabricating a magnetoresistive element, the method comprising: forming a first plurality of layers without breaking a vacuum, the first plurality of layers sequentially comprising: a first nonmagnetic conductive layer; a first ferromagnetic layer comprising an amorphous structure and a first magnetization direction; a nonmagnetic tunnel barrier layer; a second ferromagnetic layer comprising an amorphous structure and a second magnetization direction, and a getter layer having a direct contact with the second ferromagnetic layer; annealing the first plurality of layers; removing the getter layer and a portion of the second ferromagnetic layer adjacent to the getter layer; forming above the second ferromagnetic layer a second plurality of layers such that interface between the second ferromagnetic layer and the second plurality of layers is formed without breaking a vacuum after removing the getter layer and the portion of the second ferromagnetic layer, the second plurality of layers sequentially c

Abstract: According to one embodiment, a magnetoresistive effect element includes a first ferromagnetic layer, a tunnel barrier provided on the first ferromagnetic layer, and a second ferromagnetic layer provided on the tunnel barrier. The tunnel barrier includes a nonmagnetic mixture containing MgO and a metal oxide with a composition which forms, in a solid phase, a single phase with MgO.

Abstract: According to one embodiment, a magnetoresistive effect element includes a first ferromagnetic layer, a tunnel barrier formed on the first ferromagnetic layer, and a second ferromagnetic layer formed on the tunnel barrier layer. The tunnel barrier includes a nonmagnetic oxide having a spinel structure. Oxides forming the spinel structure are combined such that a single phase is formed by a solid phase in a component ratio region including a component ratio corresponding to the spinel structure and having a width of not less than 2%.