Abstract: A magnetic device includes a magnetic layer having a variable direction of magnetization, and a first antiferromagnetic layer in contact with the magnetic layer, the first antiferromagnetic layer being able to trap the direction of magnetization of the magnetic layer. The magnetic device also includes a layer made of a ferromagnetic material in contact with the first antiferromagnetic layer through its face opposite to the magnetic layer, the directions of magnetization of the magnetic and ferromagnetic layers being substantially perpendicular. A first layer among the magnetic and ferromagnetic layers has a magnetization, the direction of which is oriented in the plane of the first layer whereas the second of the two layers among the magnetic and ferromagnetic layers has a magnetization, the direction of which is oriented outside of the plane of the second layer.

Abstract: A magneto-optic surface includes a support; at least two moving elements; each of the moving elements including at least one anchoring point to the support and at least one moving part movable with respect to the support, the moving part including at least one magnetic part; the support and the moving elements being laid out in such a way that under the effect of an external magnetic field, at least one of the moving elements moves with respect to the support such that the optical properties of the magneto-optic surface are modified.

Abstract: A microparticle includes an oblong flexible tail able to propel the microparticle in a solution along a trajectory using beats transverse to the trajectory, the tail including at least one magnetic element such that the magnetic element causes beats of the tail under the action of an external alternating magnetic field non-collinear with the trajectory and a head mechanically connected to a proximal end of the tail. The microparticle includes at least one layer of material formed from one piece and including the tail and the head, the dimensions and/or shape of the head being selected such that the beats of the proximal end of the tail are limited with respect to the beats of the distal end of the tail and such that the head does not perform a complete revolution around an axis parallel to the trajectory under the effect of the external alternating magnetic field.

Abstract: According to this method for producing a magnetic tunnel junction, a film of a dielectric material capable of acting as a tunnel barrier is deposited between two nanocrystalline or amorphous magnetic films. The dielectric material constituting the tunnel barrier consists of an at least partially crystalline perovskite, and said material is deposited by ion beam sputtering in a vacuum chamber.

Abstract: A magnetic stack with out of plane magnetisation, the magnetic stack including: a first magnetic layer constituted of one or more materials selected from the following group: cobalt, iron and nickel and magnetic alloys based on the materials; a second layer constituted of a metallic material able to confer to an assembly formed by the first and the second layers a perpendicular anisotropy of interfacial origin when the second layer has a shared interface with the first layer; and a third layer deposited on the first layer, the second layer being deposited on the third layer, the third layer being constituted of a metallic material having a miscibility less than 10% with the material of the first layer.

Abstract: A magnetic thermally-assisted switching device includes a reference layer, a storage layer magnetised along a variable direction, a spacer that separates the reference layer and the storage layer, and magnetically decouples them, a device for heating the pinning layer so that, during heating, the temperature of the pinning layer exceeds its blocking temperature such that the direction of magnetisation of the storage layer is no longer pinned, a device for applying a writing magnetic torque tending to align the magnetisation of the storage layer along one of two stable magnetisation directions once the blocking temperature is reached. The device also includes a device for applying a magnetic polarisation field at least during the heating phase before the blocking temperature is reached such that the direction of magnetisation of the storage layer is always along the direction of the magnetic polarisation field at the moment that the blocking temperature is reached.

Abstract: A magnetoresistive sensor including: a first pinned-magnetization magnetic layer, called pinned layer; a free-magnetization magnetic layer, called sensitive layer, of which the magnetization, in the absence of an external field, is substantially orthogonal to the magnetization of the pinned layer, the pinned and sensitive layers being separated by a first separating layer for magnetic uncoupling; and a layer, called lateral coupling layer, located on the side of the sensitive layer opposite that of the separating layer, the lateral coupling layer serving to control the lateral spin transfer.

Abstract: A thermally assisted magnetic writing device including a first magnetic layer known as the “reference layer,” a second magnetic layer known as the “storage layer” that presents a variable magnetization direction, a spacer situated between the reference layer and the storage layer and a first antiferromagnetic layer in contact with the storage layer, the first antiferromagnetic layer being able to trap the magnetization direction of the storage layer. The magnetic device also includes a stabilization layer made of a ferromagnetic material, the stabilization layer being in contact with the first antiferromagnetic layer.

Abstract: A radio-frequency oscillator incorporates a magnetoresistive device within which an electron current is able to flow. The device includes a stack including: a magnetic trapped layer, the magnetization of which is of substantially fixed direction; a magnetic free layer; and a non-magnetic intermediate layer-interposed between the free layer and the trapped layer. The oscillator also includes a mechanism capable of making an electron current flow in the layers constituting the stack and in a direction perpendicular to the plane which contains the layers. At least the free layer is devoid of any material at its center. The electron current density flowing through the stack is capable of generating a magnetization in the free layer in a micromagnetic configuration in the shape of a skewed vortex flowing in the free layer around the center of the free layer.

Abstract: A three-layer magnetic element comprises, on a substrate, a first oxide, hydride or nitride layer O having a metal magnetic layer M mounted thereon, the latter having either a second oxide, hydride or nitride layer O?, or a non-ferromagnetic metal layer M? mounted thereon. Layer M is continuous, has a thickness of 1 to 5 nm and the magnetization thereof is parallel to the layer plane in the absence of layers O and O?. There is, for a range of temperature equal to or greater than ambient temperature, interfacial magnetic anisotropy perpendicular to the layer plane on interfaces O/M and M/O? that is capable of decreasing the effective demagnetizing field of layer M or orienting the magnetization of layer M in a manner substantially perpendicular to the layer plane.

Abstract: A magnetic device includes a reference layer, the magnetization direction of which is fixed, and a storage layer, the magnetization direction of which is variable. In a write mode, the magnetization direction of the storage layer is changed so as to store a “1” or a “0” in the storage layer. In a reading mode, the resistance of the magnetic device is measured so as to know what is stored in the storage layer. The magnetic device also includes a control layer, the magnetization direction of which is variable. The magnetization direction of the control layer is controlled so as to increase the effectiveness of the spin-transfer torque in the event writing to the storage layer is desired, and to decrease the effectiveness of the spin-transfer torque in the event reading the information contained in the storage layer, without modifying the information, is desired.

Abstract: Magnetic tweezers have two jaws formed by thin magnetic films connected together via a hinge. The magnetic tweezers include a nanoparticle formed by a stack of thin magnetic films. A process for fabricating the magnetic tweezers by techniques used in the fabrication of microelectronic components is presented.

Abstract: A spin transfer oscillator including a magnetic stack including at least two magnetic layers, at least one of the two magnetic layers is an oscillating layer that has variable direction magnetization and a current supply device configured to cause the flow of a current of electrons perpendicularly to the plane of the magnetic stack. The magnetic stack includes a device to generate inhomogeneities of current at the level of the surface of the oscillating layer and the intensity of the current supplied by the supply device is selected such that the magnetization of the oscillating layer has a consistent magnetic configuration, the magnetic configuration oscillating as a whole at the same fundamental frequency.

Abstract: The present invention relates to a magnetic recording medium (100). The invention finds a particularly interesting application in the field of data stored on hard disks. The medium (100) comprises an assembly of magnetic zones disposed on a substrate (102), each magnetic zone comprising at least one first (C?1) and one second (C?2) stacked magnetic layers separated from each other by a non-magnetic layer (NM?). In addition, said first magnetic layer (C?1) presents magnetization substantially oriented parallel to the plane of said substrate (102) and said second magnetic layer (C?2) presents magnetization substantially oriented perpendicular to the plane of said substrate (102).

Abstract: A method for manufacturing particles includes depositing on a substrate a layer of a first sacrificial material; depositing on the layer of the first sacrificial material a layer of a second sacrificial material that is different from the first sacrificial material; forming cavities in the layer of the second sacrificial material, the forming including pressing a structured mold against the layer of second sacrificial material; depositing a material for manufacturing the particles, the material covering the layer of the second material and at least partially filling the cavities; selectively removing the second sacrificial material from the first sacrificial material so as to obtain the particles formed by the material and arranged on the layer of the first sacrificial material; and eliminating the first sacrificial material to release the particles.

Abstract: A magnetic stack with out of plane magnetisation, the magnetic stack including: a first magnetic layer constituted of one or more materials selected from the following group: cobalt, iron and nickel and magnetic alloys based on the materials; a second layer constituted of a metallic material able to confer to an assembly formed by the first and the second layers a perpendicular anisotropy of interfacial origin when the second layer has a shared interface with the first layer; and a third layer deposited on the first layer, the second layer being deposited on the third layer, the third layer being constituted of a metallic material having a miscibility less than 10% with the material of the first layer.

Abstract: The present invention relates to a method of fabricating a nanostructure, comprising the following steps: prestructuring a substrate (1) adapted to receive the nanostructure to form a nanorelief (2) on the substrate, the nanorelief having flanks (4) extending from a bottom (1a) of the substrate and a top face (3) extending from said flanks, and then depositing on the substrate pre-structured in this way a single layer or multilayer coating intended to form the nanostructure; and further comprising: adding to the prestructured substrate or to the coating a separation layer adapted to enable separation of the coating and the substrate by external action of mechanical, thermomechanical or vibratory type; and exerting this external action on the substrate and/or the coating to recover selectively a top portion of the coating by separating it from the top face of the nanorelief so that this top portion constitutes some or all of the nanostructure.

Abstract: A magnetic device includes a magnetic layer having a variable direction of magnetisation, and a first antiferromagnetic layer in contact with the magnetic layer, the first antiferromagnetic layer being able to trap the direction of magnetisation of the magnetic layer. The magnetic device also includes a layer made of a ferromagnetic material in contact with the first antiferromagnetic layer through its face opposite to the magnetic layer, the directions of magnetisation of the magnetic and ferromagnetic layers being substantially perpendicular. A first layer among the magnetic and ferromagnetic layers has a magnetisation, the direction of which is oriented in the plane of the first layer whereas the second of the two layers among the magnetic and ferromagnetic layers has a magnetisation, the direction of which is oriented outside of the plane of the second layer.

Abstract: A magnetic device includes a magnetic reference layer with a fixed magnetization direction located either in the plane of the layer or perpendicular to the plane of the layer, a magnetic storage layer with a variable magnetization direction, a non-magnetic spacer separating the reference layer and the storage layer and a magnetic spin polarizing layer with a magnetization perpendicular to that of the reference layer, and located out of the plane of the spin polarizing layer if the magnetization of the reference layer is directed in the plane of the reference layer or in the plane of the spin polarizing layer if the magnetization of the reference layer is directed perpendicular to the plane of the reference layer. The spin transfer coefficient between the reference layer and the storage layer is higher than the spin transfer coefficient between the spin polarizing layer and the storage layer.

Abstract: This magnetic multilayer device comprises, on a substrate, an alternating sequence of magnetic metallic layers M and oxide, hydride or nitride layers O. The number of layers M equals at least two. The layers M are continuous. There is interfacial magnetic anisotropy perpendicular to the plane of the layers at the level of the M/O interfaces.