Abstract: A magnetic memory device of MRAM type with a thermally-assisted writing procedure, the magnetic memory device being formed from a plurality of memory cells, each memory cell comprising a magnetic tunnel junction, the magnetic tunnel junction comprising a magnetic storage layer in which data can be written in a writing process; a reference layer, having a magnetization being always substantially in the same direction at any time of the writing process; an insulating layer between the reference layer and the storage layer; wherein the magnetic tunnel junction further comprises a writing layer made of a ferrimagnetic 3d-4f amorphous alloy, and comprising a net magnetization containing a first magnetization contribution originating from the sub-lattice of 3d transition elements and a second magnetization contribution originating from the sub-lattice of 4f rare-earth elements. The magnetic memory device has a low power consumption.

Abstract: A method of writing in a memory device comprising a plurality of MRAM cells, each cell including a magnetic tunnel junction having a resistance that can be varied during a write operation when heated at a high threshold temperature; a plurality of word lines connecting cells along a row; and a plurality of bit lines connecting cells along a column; the method comprising supplying a bit line voltage to one of the bit lines and a word line voltage to one of the word lines for passing a heating current through the magnetic tunnel junction of a selected cell; said word line voltage is a word line overdrive voltage being higher than the core operating voltage of the cells such that the heating current has a magnitude that is high enough for heating the magnetic tunnel junction at the predetermined high threshold temperature. The memory device can be written with low power consumption.

Abstract: The present disclosure concerns a magnetic element to be written using a thermally-assisted switching write operation comprising a magnetic tunnel junction formed from a tunnel barrier being disposed between first and second magnetic layers, said second magnetic layer having a second magnetization which direction can be adjusted during a write operation when the magnetic tunnel junction is heated at a high threshold temperature; an upper current line connected at the upper end of the magnetic tunnel junction; and a strap portion extending laterally and connected to the bottom end of the magnetic tunnel junction; the magnetic device further comprising a bottom thermal insulating layer extending substantially parallel to the strap portion and arranged such that the strap portion is between the magnetic tunnel junction and the bottom thermal insulating layer. The magnetic element allows for reducing heat losses during the write operation and has reduced power consumption.

Abstract: A magnetic tunnel junction (MTJ)-based magnetic random access memory (MRAM) cell with a thermally assisted switching (TAS) writing procedure and methods for manufacturing and using same. The TAS MTJ-based MRAM cell includes a magnetic tunnel junction that is formed with an anisotropic shape and that comprises a ferromagnetic storage layer, a reference layer, and an intermediate insulating layer. The ferromagnetic storage layer has a magnetization that is adjustable above a high temperature threshold; whereas, the reference layer has a fixed magnetization. The ferromagnetic storage layer is provided with a magnetocrystalline anisotropy that is oriented essentially perpendicular to a long axis of the anisotropic shape of the magnetic tunnel junction.

Abstract: A memory unit with one field line; at least two thermally-assisted switching magnetic tunnel junction-based magnetic random access memory cells, each cell comprising a magnetic tunnel junction having an insulating layer disposed between a magnetic storage layer and a magnetic reference layer; wherein a selection transistor is connected to the magnetic tunnel junction; the one field line is used for passing a field current for switching a magnetization of the storage layer of the magnetic tunnel junctions of the cells. A magnetic memory device can be formed by assembling an array of the memory units, wherein at least two adjacent magnetic tunnel junctions of the cells can be addressed simultaneously by the field line. The memory unit and magnetic memory device have a reduced surface area. Magnetic memory devices with an increased density of memory units can be fabricated resulting in lower die fabrication cost and lower power consumption.

Abstract: A memory device comprising: a plurality of magnetoresistive random access memory (MRAM) cells arranged in rows and columns, each MRAM cell comprising a magnetic tunnel junction and a select transistor, one end of the magnetic tunnel junction being electrically coupled to the source of the select transistor; a plurality of word lines, each word line connecting MRAM cells along a row via the gate of their select transistor; a plurality of bit lines, each bit line connecting MRAM cells along a column, each bit line connecting the MRAM cells via the drain of their select transistor; wherein the memory device further comprises a plurality of source lines, each source line connecting MRAM cells along a row; and wherein each source line connecting the MRAM cells via the other end of the magnetic tunnel junction.

Abstract: A magnetic random access memory (MRAM) cell with a thermally assisted switching (TAS) writing procedure, comprising a magnetic tunnel junction formed from a ferromagnetic storage layer having a first magnetization adjustable at a high temperature threshold, a ferromagnetic reference layer having a fixed second magnetization, and an insulating layer, said insulating layer being disposed between the ferromagnetic storage and reference layers; a select transistor being electrically connected to said magnetic tunnel junction and controllable via a word line; a current line, electrically connected to said magnetic tunnel junction, passing at least a write current; characterized in that the magnetocrystalline anisotropy of the ferromagnetic storage layer is substantially orthogonal with the magnetocrystalline anisotropy of the ferromagnetic reference layer. The STT-based TAS-MRAM cell achieves simultaneously thermal stability and requires low write current density.

Abstract: Disclosed herein is a thermally-assisted magnetic tunnel junction structure including a thermal barrier. The thermal barrier is composed of a cermet material in a disordered form such that the thermal barrier has a low thermal conductivity and a high electric conductivity. Compared to conventional magnetic tunnel junction structures, the disclosed structure can be switched faster and has improved compatibility with standard semiconductor fabrication processes.

Abstract: Controllable readout circuit for performing a self-referenced read operation on a memory device comprising a plurality of magnetic random access memory (MRAM) cells comprising a selecting device for selecting one of the MRAM cells, and a sense circuit for sourcing a sense current to measure the first and second resistance value; the sense circuit comprising a sample and hold circuit for performing said storing said first resistance value, and a differential amplifier circuit for performing said comparing the second resistance value to the stored first resistance value; wherein the controllable readout circuit further comprises a control circuit adapted to provide a pulse-shaped timing signal with a pulse duration controlling the duration of the first read cycle and the second read cycle. The controllable readout circuit allows for controlling the duration of the first and second read cycles after completion of the MRAM cell and readout circuit fabrication.

Abstract: A content-addressable random access memory having magnetic tunnel junction-based memory cells and methods for making and using same. The magnetic tunnel junction has first and second magnetic layers and can act as a data store and a data sense. Within each cell, registered data is written by setting a magnetic orientation of the first magnetic layer in the magnetic tunnel junction via current pulses in one or more current lines. Input data for comparison with the registered data can be similarly set through the magnetic orientation of the second magnetic layer via the current lines. The data sense is performed by measuring cell resistance, which depends upon the relative magnetic orientation of the magnetic layers. Since data storage, data input, and data sense are integrated into one cell, the memory combines higher densities with non-volatility. The memory can support high speed, reduced power consumption, and data masking.

Abstract: A magnetic tunnel junction, comprising a reference layer having a fixed magnetization direction, a first storage layer having a magnetization direction that is adjustable relative to the magnetization direction of the reference layer by passing a write current through said magnetic tunnel junction, and an insulating layer disposed between said reference layer and first storage layer; characterized in that the magnetic tunnel junction further comprises a polarizing device to polarize the spins of the write current oriented perpendicular with the magnetization direction of the reference layer; and wherein said first storage layer has a damping constant above 0.02. A magnetic memory device formed by assembling an array of the magnetic tunnel junction can be fabricated resulting in lower power consumption.

Abstract: The present disclosure concerns a magnetic random access memory cell containing a magnetic tunnel junction formed from an insulating layer comprised between a sense layer and a storage layer. The present disclosure also concerns a method for writing and reading the memory cell comprising, during a write operation, switching a magnetization direction of said storage layer to write data to said storage layer and, during a read operation, aligning magnetization direction of said sense layer in a first aligned direction and comparing said write data with said first aligned direction by measuring a first resistance value of said magnetic tunnel junction. The disclosed memory cell and method allow for performing the write and read operations with low power consumption and an increased speed.

Abstract: The present disclosure concerns a magnetic random access memory-based ternary content addressable memory cell, comprising a first and second magnetic tunnel junction respectively connected to a first and second straps extending on each side of the first and second magnetic tunnel junctions, respectively; a first and second selection transistors, respectively connected to one extremity of the first and second straps; a first and second current lines; and a conductive line electrically connecting in series the first and second magnetic tunnel junctions at their ends opposed to the ones connecting the first and second straps. The cell disclosed herein has smaller size and can be advantageously used in memory devices having a high cell density array.

Abstract: Magnetic element with thermally-assisted magnetic-field writing or thermally-assisted spin-transfer writing, comprising: a reference magnetic layer having a fixed direction magnetization; a storage magnetic layer exchange-pinned with an antiferromagnetic layer, wherein the magnetization direction of the storage layer can vary when said element can be heated to a temperature at least higher than a critical temperature of the antiferromagnetic layer; a tunnel barrier, provided between the reference layer and the storage layer; wherein the magnetic reference layer, and/or the magnetic storage layer includes at least one electrically-resistive thin layer for heating the magnetic element. The magnetic element disclosed herein has a voltage gain of typically 10 to 50% compared to conventional magnetic elements and shows a reduction of the stress induced during a writing operation as well as a reduction of the ageing.

Abstract: The present disclosures concerns a register cell comprising a differential amplifying portion containing a first inverter coupled to a second inverter such as to form an unbalanced flip-flop circuit; a first and second bit line connected to one end of the first and second inverter, respectively; and a first and second source line connected to the other end of the first and second inverter, respectively; characterized by the register cell further comprising a first and second magnetic tunnel junction electrically connected to the other end of the first and second inverter, respectively. The shift register disclosed herein can be made smaller than conventional shift registers and power consumption during the write and read operation of the shift registers can be low. The shift register disclosed herein can be made smaller than conventional shift registers and power consumption during the write and read operation of the shift registers can be low.

Abstract: A magnetic random access memory (MRAM) cell with a thermally assisted switching (TAS) writing procedure, comprising a magnetic tunnel junction formed from a ferromagnetic storage layer having a first magnetization adjustable at a high temperature threshold, a ferromagnetic reference layer having a fixed second magnetization direction, and an insulating layer, said insulating layer being disposed between the ferromagnetic storage and reference layers; a select transistor being electrically connected to said magnetic tunnel junction and controllable via a word line; a current line electrically connected to said magnetic tunnel junction; characterized in that the magnetocrystalline anisotropy of the ferromagnetic storage layer is essentially orthogonal with the magnetocrystalline anisotropy of the ferromagnetic reference layer. The TAS-MRAM cell of the invention can be written with a smaller magnetic field than the one used in conventional TAS-MRAM cells and has low power consumption.

Abstract: A magnetic memory device of MRAM type with a thermally-assisted writing procedure, the magnetic memory device being formed from a plurality of memory cells, each memory cell comprising a magnetic tunnel junction, the magnetic tunnel junction comprising a magnetic storage layer in which data can be written in a writing process; a reference layer, having a magnetization being always substantially in the same direction at any time of the writing process; an insulating layer between the reference layer and the storage layer; wherein the magnetic tunnel junction further comprises a writing layer made of a ferrimagnetic 3d-4f amorphous alloy, and comprising a net magnetization containing a first magnetization contribution originating from the sub-lattice of 3d transition elements and a second magnetization contribution originating from the sub-lattice of 4f rare-earth elements. The magnetic memory device has a low power consumption.

Abstract: A content-addressable random access memory having magnetic tunnel junction-based memory cells and methods for making and using same. The magnetic tunnel junction has first and second magnetic layers and can act as a data store and a data sense. Within each cell, registered data is written by setting a magnetic orientation of the first magnetic layer in the magnetic tunnel junction via current pulses in one or more current lines. Input data for comparison with the registered data can be similarly set through the magnetic orientation of the second magnetic layer via the current lines. The data sense is performed by measuring cell resistance, which depends upon the relative magnetic orientation of the magnetic layers. Since data storage, data input, and data sense are integrated into one cell, the memory combines higher densities with non-volatility. The memory can support high speed, reduced power consumption, and data masking.

Abstract: A magnetic random access memory (MRAM) cell with a thermally assisted writing procedure comprising a magnetic tunnel junction formed from a magnetic storage layer, a reference layer, and an insulating layer inserted between the reference layer and the storage layer; and a first strap portion laterally connecting one end of the magnetic tunnel junction to a first selection transistor; wherein the cell further comprises a second strap portion extending opposite to the first strap portion and connecting laterally said one end of the magnetic tunnel junction to a second selection transistor, and in that said first and second strap portions being adapted for passing a portion of current via the first and second selection transistors. The disclosed cell has lower power consumption than conventional MRAM cells.

Abstract: A method for writing a magnetic random access memory-based ternary content addressable memory cell comprising a first magnetic tunnel junction being formed from a storage layer, a sense layer having a magnetization direction adjustable relative to the magnetization of the storage layer, and an insulating layer between the storage and sense layers; a sense line coupled with the storage layer; a first field line and a second field line, and the first field line being orthogonal to the second field line; comprising: providing a first write data to said storage layer via the second field line to store a first stored data with a high or low logic state; characterized in that, the method further comprises providing the first write data to said storage layer via the first field line to store the first stored data with a masked logic state.