Abstract: In one embodiment, there is provided a non-volatile magnetic memory cell. The non-volatile magnetic memory cell comprises a switchable magnetic element; and a word line and a bit line to energize the switchable magnetic element; wherein at least one of the word line and the bit line comprises a magnetic sidewall that is discontinuous.

Abstract: In one embodiment of the invention, there is provided a method for manufacturing a magnetic memory device, comprising: depositing a carbon layer comprising amorphous carbon on a substrate; annealing the carbon layer to activate dopants contained therein; and selectively etching portions of the carbon layer to forms lines of spaced apart carbon conductors.

Abstract: Integrated circuit comprising a sensing unit that includes a sensing circuit, two conductors and a magnetic storage element. The sensing circuit monitors a voltage drop across the element when a current is passed between the conductors with the element in between. The voltage drop is pre-calibrated to indicate a change in conductivity in the element that is caused by an external magnetic field. Advantageously, this indication is usable particularly for assessing a possible data corruption in a magnetic memory circuit in the integrated circuit, due to stray and external magnetic fields. Methods of using the sensing unit are also proposed.

Abstract: There is provided a method for operating a magnetic memory device. The method comprises selecting a subset of magnetic memory cells of the magnetic memory device; applying a first programming voltage to the selected subset of cells for a predetermined amount of time, wherein the programming voltage is selected to exceed a threshold operating voltage thereby to cause irreversible breakdown of the subset of cells; and reading selected cells of the magnetic memory device by passing a read current through a diode connected in series with each magnetic memory cell.

Abstract: In one embodiment of the invention, there is provided a magnetic random access (MRAM) device. The device comprises a plurality of MRAM cells, wherein each MRAM cell comprises a magnetic bit, and write conductors defined by conductors patterned in a second metal layer above the magnetic bit; and a gate formed below the magnetic bit between a source and a drain; and addressing circuits to address the MRAM cells.

Abstract: In one embodiment, there is provided a non-volatile magnetic memory cell. The non-volatile magnetic memory cell comprises a switchable magnetic element; and a word line and a bit line to energize the switchable magnetic element; wherein at least one of the word line and the bit line comprises a magnetic sidewall that is discontinuous.

Abstract: Embodiments of the invention disclose magnetic memory cell configurations in which a magnetic storage structure is coupled to an upper metal layer with minimal overlay margin. This greatly reduces a size of the memory cell.

Abstract: Disclosed is a memory circuit and method of forming the same. The memory circuit comprises a lower metallization layer defining first conducting lines. A continuous magnetic storage element stack is atop the lower metallization layer wherein a bottom electrode of the stack is in direct contact with the first conducting lines. An upper metallization layer is atop the continuous magnetic storage element stack, the upper metallization layer defining second conducting lines, which are in direct contact with said continuous magnetic storage element stack. Localized areas of the continuous magnetic storage element stack define discrete magnetic bits, each energizable through a selected pair of the first and second conducting lines. In a second aspect and a third aspect, the continuous magnetic storage element stack is respectively partially and fully etched through a single mask, to define the discrete magnetic bits.

Abstract: Integrated circuit comprising a sensing unit that includes a sensing circuit, two conductors and a magnetic storage element. The sensing circuit monitors a voltage drop across the element when a current is passed between the conductors with the element in between. The voltage drop is pre-calibrated to indicate a change in conductivity in the element that is caused by an external magnetic field. Advantageously, this indication is usable particularly for assessing a possible data corruption in a magnetic memory circuit in the integrated circuit, due to stray and external magnetic fields. Methods of using the sensing unit are also proposed.

Abstract: A method for fabricating a magnetic film structure is provided. The method comprises forming a magnetic structure on a bottom electrode layer, the magnetic structure comprising at least one pinned bottom magnetic film layer having a fixed magnetic orientation; at least one top magnetic film layer whose magnetic orientation can be manipulated by a current; and a tunneling layer between the bottom magnetic film layer and the top magnetic film layer; forming a metallic hard mask atop the magnetic structure; patterning and etching the metallic hard mask to define exposed areas of the magnetic structure; selectively etching the exposed areas of the magnetic structure by a chemical etch process based on a CO etch chemistry to form discrete magnetic bits.

Abstract: Memory circuit comprising an addressable magnetic tunnel junction (MTJ) stack, forming a magnetic storage element in the circuit. The MTJ stack comprises a tunnel oxide layer between a free layer and a fixed layer. A stress inducing layer is disposed adjacent to the free layer to provide tensile or compressive stress to the free layer, in order to manipulate a magnetic field that is required to write a bit into the MTJ stack. Method of using the memory circuit is also proposed.

Abstract: A semiconductor integrated circuit comprising a first circuit area for a low voltage operation and a second circuit area for a high voltage operation. The circuit areas comprise two vertically stacked backend patterned metal layers that are separated by an inter-metallic dielectric (IMD). The two metal layers and the IMD form a combination that is operable at the low voltage. The first circuit area uses a first portion of the combination for operating at the low voltage and the second circuit area uses a second portion of the combination for routing at the high voltage, the two metal layers in the second portion being interconnected through the IMD by via hole, for withstanding the high voltage. The first portion may comprise an array of magnetic random access memory (MRAM) devices and the second circuit area may comprise a display drive circuit.

Abstract: A method for fabricating a magnetic film structure is provided. The method comprises forming a magnetic structure on a bottom electrode layer, the magnetic structure comprising at least one pinned bottom magnetic film layer having a fixed magnetic orientation; at least one top magnetic film layer whose magnetic orientation can be manipulated by a current; and a tunneling layer between the bottom magnetic film layer and the top magnetic film layer; forming a metallic hard mask atop the magnetic structure; patterning and etching the metallic hard mask to define exposed areas of the magnetic structure; selectively etching the exposed areas of the magnetic structure by a chemical etch process based on a CO etch chemistry to form discrete magnetic bits.

Abstract: A method for fabricating a circuit, by defining a first set of resist features on a substrate and corresponding to a first mask layout, followed by defining a second set of resist features on the substrate corresponding to a second mask layout, wherein the second set adds to the first set for rectifying an error in either mask layout. In another aspect, the method is by defining a first set of resist features on a substrate and corresponding to a first mask layout that has an error, etching the substrate while the first set protects selected regions, defining a second set of resist features on the substrate and corresponding to a second mask layout, followed by etching the substrate to selectively remove portions of the selected regions for rectifying the error.

Abstract: Memory circuit comprising an addressable magnetic tunnel junction (MTJ) stack, forming a magnetic storage element in the circuit. The MTJ stack comprises a tunnel oxide layer between a free layer and a fixed layer. A stress inducing layer is disposed adjacent to the free layer to provide tensile or compressive stress to the free layer, in order to manipulate a magnetic field that is required to write a bit into the MTJ stack. Method of using the memory circuit is also proposed.

Abstract: Embodiments of the present invention disclose an MRAM cell layout for 32 nm, 45 nm, and 65 nm CMOS process technology.

Abstract: Disclosed is a memory circuit and method of forming the same. The memory circuit comprises a lower metallization layer defining first conducting lines. A continuous magnetic storage element stack is atop the lower metallization layer wherein a bottom electrode of the stack is in direct contact with the first conducting lines. An upper metallization layer is atop the continuous magnetic storage element stack, the upper metallization layer defining second conducting lines, which are in direct contact with said continuous magnetic storage element stack. Localized areas of the continuous magnetic storage element stack define discrete magnetic bits, each energizable through a selected pair of the first and second conducting lines. In a second aspect and a third aspect, the continuous magnetic storage element stack is respectively partially and fully etched through a single mask, to define the discrete magnetic bits.

Abstract: A novel magnetic memory cell utilizing nanotubes as conducting leads. The magnetic memory cell may be built based on MTJ (Magnetic Tunnel Junction) or GMR (Giant Magneto Resistance) sensors or devices of similar nature. A SET (Single Electron Transistor) made of semiconducting nanotubes may be used as access devices and/or to build peripheral circuitry.

Abstract: In one embodiment of the invention, there is provided a method for manufacturing a magnetic memory device, comprising: depositing a carbon layer comprising amorphous carbon on a substrate; annealing the carbon layer to activate dopants contained therein; and selectively etching portions of the carbon layer to forms lines of spaced apart carbon conductors.

Abstract: Memory circuit and method for at least partially dissipating an external magnetic field before the magnetic field affects operation of an array of addressable magnetic storage element stacks in the memory circuit. Multiple dummy magnetic storage element stacks are provided around the periphery of the array. Each of the dummy stacks is substantially circular for orienting along the external magnetic field, thereby causing the dissipation. Each of the addressable and the dummy stacks may be formed with a magnetic tunnel junction (MTJ).