Abstract: Magnetic element including a first ferromagnetic layer having a first magnetization including a stable magnetization vortex configuration having a vortex core. The first ferromagnetic layer includes an indentation configured such that the vortex core nucleates substantially at the indentation. Upon application of an external magnetic field in a first field direction, the vortex core moves along a first path and the first magnetization rotates around the vortex core in a counterclockwise direction. Upon application of the external magnetic field in a second field direction opposed to the first field direction, the vortex core moves along a second path and the first magnetization rotates around the vortex core in a clockwise direction. Both the first and second field path are substantially identical and move the vortex core away from the indentation.

Abstract: A cryogenic magnetic device includes a free layer having a free magnetisation and a magnetic anisotropy favouring the orientation of the free magnetisation according to a first orientation or a second orientation, the magnetic anisotropy being defined by an energy barrier separating the first orientation and the second orientation, the amplitude of the energy barrier being less than 6300 kB, the free layer having a Gilbert damping factor comprised between 0.02 and 0.4; a tunnel barrier extending in contact with the free layer; and a system configured to apply a voltage pulse through the tunnel barrier so as to reduce the amplitude of the energy barrier and switch the free magnetisation.

Abstract: Magnetic element including a first ferromagnetic layer having a first magnetization including a stable magnetization vortex configuration having a vortex core. The first ferromagnetic layer includes an indentation configured such that the vortex core nucleates substantially at the indentation. Upon application of an external magnetic field in a first field direction, the vortex core moves along a first path and the first magnetization rotates around the vortex core in a counterclockwise direction. Upon application of the external magnetic field in a second field direction opposed to the first field direction, the vortex core moves along a second path and the first magnetization rotates around the vortex core in a clockwise direction. Both the first and second field path are substantially identical and move the vortex core away from the indentation.

Abstract: A method for manufacturing a spintronic device including a non-magnetic spacer, a reference layer and a storage layer including a magnetic pillar, the method including depositing at least one sacrificial layer; forming at least one flared cavity, traversing the sacrificial layer; depositing at least one magnetic layer in the cavity; eliminating the excess of magnetic layer outside of the cavity; removing the dielectric layer in order to form at least one magnetic pillar forming all or part of the storage layer; depositing at least the non-magnetic spacer and the reference layer; filling the spaces between the magnetic pillars with a dielectric material; carrying out a polishing; forming an electrical contact on the surface of the element surmounting the magnetic pillar.

Abstract: A magnetic tunnel junction includes at least one free layer, at least one reference layer, and at least one tunnel barrier separating the free layer and the reference layer, wherein the free layer is an inhomogeneous granular layer including at least two grains, each grain of the at least two grains being sensibly magnetically decoupled from the other adjacent grains of the at least two grains.

Abstract: A magnetic stack includes a first element including a ferromagnetic layer; a second element including a metal layer able to confer on the assembly formed by the first and the second elements a magnetic anisotropy perpendicular to the plane of the layers. The first element further includes a refractory metal material, the second element being arranged on the first element.

Abstract: A magnetic tunnel junction with out-of-plane magnetisation includes a storage layer; a reference layer; a tunnel barrier layer, the two magnetisation states of the storage layer being separated by an energy barrier, the magnetic tunnel junction having a thermal stability factor dependent on the energy barrier and on the temperature of use of the magnetic tunnel junction. The storage layer has a thickness comprised between 0.5 times and 8 times a characteristic dimension of a planar section of the tunnel junction; the composition and the thickness of the storage layer are chosen such that the absolute value of the derivative of the thermal stability factor compared to a characteristic dimension of a planar section of the tunnel junction is less than 10 nm?1.

Abstract: A magnetic tunnel junction with out-of-plane magnetisation includes a storage layer; a reference layer; and a tunnel barrier layer. The two magnetisation states of the storage layer are separated by an energy barrier including a contribution due to the shape anisotropy of the storage layer and a contribution of interfacial origin for each interface of the storage layer. The storage layer has a thickness comprised between 0.8 and 8 times a characteristic dimension of a planar section of the tunnel junction. The contribution to the energy barrier due to the shape anisotropy of the storage layer is at least two times greater and preferably at least 4 times greater than the contributions to the energy barrier of interfacial origin.

Abstract: A synthetic antiferromagnetic layer includes a first ferromagnetic layer containing an amorphizing element, the first ferromagnetic layer having a first structural symmetry; a second ferromagnetic layer having a second structural symmetry; wherein the first and the second ferromagnetic layers are antiferromagnetically coupled by a trifunctional non-magnetic multi-layered structure, the antiferromagnetic coupling being an Ruderman-Kittel-Kasuya-Yosida (RKKY) coupling, the non-magnetic multi-layered structure including at least two non-magnetic layers, the non-magnetic multilayered structure being at least partially nano-crystalline or amorphous in order to ensure a structural transition between the first ferromagnetic layer having the first structural symmetry and the second ferromagnetic layer having the second structural symmetry, the non-magnetic multilayered structure being adapted to absorb at least part of the amorphizing element out of the first ferromagnetic layer in contact with the non-magnetic multi

Abstract: A magnetic tunnel junction with out-of-plane magnetisation includes a storage layer; a reference layer; a tunnel barrier layer, the two magnetisation states of the storage layer being separated by an energy barrier, the magnetic tunnel junction having a thermal stability factor dependent on the energy barrier and on the temperature of use of the magnetic tunnel junction. The storage layer has a thickness comprised between 0.5 times and 8 times a characteristic dimension of a planar section of the tunnel junction; the composition and the thickness of the storage layer are chosen such that the absolute value of the derivative of the thermal stability factor compared to a characteristic dimension of a planar section of the tunnel junction is less than 10 nm?1.

Abstract: A method for manufacturing a biocompatible fluid including a powder of magnetic particles of elongated shape having a magnetic shape anisotropy and having a final granulometry, the final granulometry being defined by a first average size of the particles in a first direction and a second average size in a second direction different from the first direction, the final granulometry further being defined by a first distribution width of the first sizes and a second distribution width of the second sizes, the method including from a powder of magnetic particles having an initial granulometry different from the final granulometry, modification of the initial granulometry by milling and/or by sintering of the powder until the final granulometry is obtained; introduction of the powder of magnetic particles into a biocompatible fluid.

Abstract: A magnetic tunnel junction with out-of-plane magnetisation includes a storage layer; a reference layer; and a tunnel barrier layer. The two magnetisation states of the storage layer are separated by an energy barrier including a contribution due to the shape anisotropy of the storage layer and a contribution of interfacial origin for each interface of the storage layer. The storage layer has a thickness comprised between 0.8 and 8 times a characteristic dimension of a planar section of the tunnel junction. The contribution to the energy barrier due to the shape anisotropy of the storage layer is at least two times greater and preferably at least 4 times greater than the contributions to the energy barrier of interfacial origin.

Abstract: A magnetic stack includes a first element including a ferromagnetic layer; a second element including a metal layer able to confer on the assembly formed by the first and the second elements a magnetic anisotropy perpendicular to the plane of the layers. The first element further includes a refractory metal material, the second element being arranged on the first element.

Abstract: A synthetic antiferromagnetic layer includes a first ferromagnetic layer containing an amorphizing element, the first ferromagnetic layer having a first structural symmetry; a second ferromagnetic layer having a second structural symmetry; wherein the first and the second ferromagnetic layers are antiferromagnetically coupled by a trifunctional non-magnetic multi-layered structure, the antiferromagnetic coupling being an RKKY coupling, the non-magnetic multi-layered structure including at least two non-magnetic layers, the non-magnetic multilayered structure being at least partially nano-crystalline or amorphous in order to ensure a structural transition between the first ferromagnetic layer having the first structural symmetry and the second ferromagnetic layer having the second structural symmetry, the non-magnetic multilayered structure being adapted to absorb at least part of the amorphizing element out of the first ferromagnetic layer in contact with the non-magnetic multi-layered structure.

Abstract: A method for manufacturing a resistive device, includes depositing a first electrically conductive layer on a substrate; forming an etching mask on the first conductive layer; etching the first conductive layer through the mask, such as to obtain a plurality of electrically conductive pillars separated from one another; and forming storage elements with variable electrical resistance at the tops of the electrically conductive pillars, such that each storage element is supported by one of the electrically conductive pillars, the step of forming the storage elements including the following operations depositing a first layer by non-collimated cathode sputtering at normal incidence relative to the substrate; and depositing a second layer on the first layer by cathode sputtering, the second layer including a first chemical species sputtered at an oblique incidence.

Abstract: A magnetic field sensor includes first and second sensors for detecting first and second magnetic components according to first and second directions. Each sensor includes a flux concentrator including first and second magnetic parts, an air gap between the parts, and a magnetoresistive element in the air gap. Each magnetoresistive element includes a reference layer having a fixed magnetization direction, the fixed magnetization direction of the first and second sensors being substantially identical, and a sensitive layer having a variable magnetization direction, the variable magnetization direction of the first sensor when the first sensor is in a state of rest being substantially identical to the variable magnetization direction of the second sensor when the second sensor is in the state of rest. The air gaps of first and second sensor are oriented parallel to a direction XY which is, at ±15°, the bisector of the first and second directions.

Abstract: A method for manufacturing a resistive device, includes depositing a first electrically conductive layer on a substrate; forming an etching mask on the first conductive layer; etching the first conductive layer through the mask, such as to obtain a plurality of electrically conductive pillars separated from one another; and forming storage elements with variable electrical resistance at the tops of the electrically conductive pillars, such that each storage element is supported by one of the electrically conductive pillars, the step of forming the storage elements including the following operations depositing a first layer by non-collimated cathode sputtering at normal incidence relative to the substrate; and depositing a second layer on the first layer by cathode sputtering, the second layer including a first chemical species sputtered at an oblique incidence.

Abstract: A magnetic logic unit (MLU) cell includes a first magnetic tunnel junction and a second magnetic tunnel junction, each magnetic tunnel junction including a first magnetic layer having a first magnetization, a second magnetic layer having a second magnetization, and a tunnel barrier layer between the first and second layer. A field line for passing a field current such as to generate an external magnetic field is adapted to switch the first magnetization. The first magnetic layer is arranged such that the magnetic tunnel junction magnetization varies linearly with the generated external magnetic field. An MLU amplifier includes a plurality of the MLU cells. The MLU amplifier has large gains, extended cut off frequencies and improved linearity.

Abstract: A thermally-assisted magnetic writing device includes at least one magnetic element including: a reference layer having a stable vortex magnetization configuration; a device to create a magnetic field to reversibly move the vortex core in the plane of the reference layer; a storage layer having a variable magnetization configuration; a non-magnetic spacer that separates and magnetically decouples the reference layer and the storage layer; an antiferromagnetic pinning layer in contact with the storage layer, the antiferromagnetic layer being capable of pinning the magnetization configuration of the storage layer, the storage layer having at least two storage levels corresponding to two pinned magnetization configurations; a device to heat the antiferromagnetic pinning layer such that when heated, the temperature of the antiferromagnetic pinning layer exceeds its blocking temperature such that the magnetization configuration of the storage layer is no longer pinned when warm.

Abstract: A voltage-controlled spintronic device includes a magnetic layer having an effective anisotropy Keff; a non-magnetic insulating layer; a contact layer; the magnetic layer having an anisotropy switching threshold such that application of a polarization voltage Vmax allows switching of the effective anisotropy Keff from a direction perpendicular to the reference plane to a direction in the reference plane or vice versa, the magnetic layer including a first layer, with thickness tB, having a volume anisotropy KVB; a second layer, with thickness tA, having a surface anisotropy KSA and a volume anisotropy KVA; the surface anisotropy KSA and the volume anisotropies KVA and KVB respecting, over a given operating temperature range: Min(KSA(V=0), KSA(V=Vmax))<?{KVBtB+KVAtA)<Max(KSA(V=0), KSA(V=Vmax)). KSA(V=0) is the surface anisotropy when no polarization voltage is applied. KSA(V=Vmax) is the surface anisotropy when a polarization voltage Vmax is applied.