Abstract: A method and system for a high current semiconductor memory cell provides a semiconductor memory cell with two current carrying structures. At least one of the current carrying structures is segmented and formed of narrow wire segments from one or more levels coupled to wider connective squares of another level. The wire segments may be a conductive material and the connective squares a refractory material. The short length wire segments may include a length less than the average grain size of the material of which they are formed.

Abstract: A method of manufacturing a memory device is provided. The method includes forming an electrode over a substrate. The method also includes forming an opening in the electrode to provide a tapered electrode contact surface proximate the opening. The method further includes forming a phase change feature over the electrode and on the tapered electrode contact surface.

Abstract: A non-destructive technique and related array for writing and reading magnetic memory cells, including sampling a first signal of a selected read line corresponding to select memory cells, applying a magnetic field to the select memory cells, sampling a second signal of the selected read line, and comparing the first and second signals to determine a logic state of the select memory cells.

Abstract: A phase change memory device and a method of forming the same are provided. The phase change memory device includes a conducting electrode in a dielectric layer, a bottom electrode over the conducting electrode, a phase change layer over the bottom electrode, and a top electrode over the phase change layer. The phase change memory device may further include a heat sink layer between the phase change layer and the top electrode. The resistivities of the bottom electrode and the top electrode are preferably greater than the resistivity of the phase change material in the crystalline state.

Abstract: A method for forming semi-insulating portions in a semiconductor substrate provides depositing a hardmask film over a semiconductor substructure to a thickness sufficient to prevent charged particles from passing through the hardmask. The hardmask is patterned creating openings through which charged particles pass and enter the substrate during an implantation process. The semi-insulating portions may extend deep into the semiconductor substrate and electrically insulate devices formed on opposed sides of the semi-insulating portions. The charged particles may advantageously be protons and further substrate portions covered by the patterned hardmask film are substantially free of the charged particles.

Abstract: A magnetic shielding device is provided for protecting at least one magnetically sensitive component on a substrate according to embodiments of the present invention. The device comprises a first shield having a top portion, and one or more side portions, wherein the top and side portions along with the substrate encloses the magnetic sensitive component within for protecting the same from an external magnetic field, and wherein the magnetic shielding device contains at least two magnetic shielding materials with one having a relatively higher magnetic permeability property but lower magnetic saturation property while the other having a relatively lower magnetic permeability property but higher magnetic saturation property.

Abstract: A non-destructive technique and related array for writing and reading magnetic memory cells, including sampling a first signal of a selected read line corresponding to select memory cells, applying a magnetic field to the select memory cells, sampling a second signal of the selected read line, and comparing the first and second signals to determine a logic state of the select memory cells.

Abstract: A method and system is disclosed for concentrating high energy particles on a predetermined area on a target semiconductor substrate. A high energy source for generating a predetermined amount of high energy particles, and an electro-magnetic radiation source for generating low energy beams are used together. The system also uses a mask set having at least one mask with at least one alignment area and at least one mask target area thereon, the mask target area passing more high energy particles then any other area of the mask. At least one protection shield is incorporated in the system for protecting the alignment area from being exposed to the high energy particles, wherein the mask is aligned with the predetermined target semiconductor substrate by passing the low energy beams through the alignment area, wherein the high energy particles generated by the high energy source pass through the mask target area to land on the predetermined area on the target semiconductor substrate.

Abstract: A magnetic random access memory device (MRAM) and the method for forming the same are disclosed. The MRAM has a magnetic tunnel junction (MTJ) device, a first write line, and a second write line orthogonal to the first write line, wherein at least one of the first and second write lines has a width narrower than that of the MTJ.

Abstract: Disclosed herein is a magnetoresistive structure, for example useful as a spin-valve or GMR stack in a magnetic sensor, and a fabrication method thereof. The magnetoresistive structure uses twisted coupling to induce a perpendicular magnetization alignment between the free layer and the pinned layer. Ferromagnetic layers of the free and pinned layers are exchange-coupled using antiferromagnetic layers having substantially parallel exchange-biasing directions. Thus, embodiments can be realized that have antiferromagnetic layers formed of a same material and/or having a same blocking temperature. At least one of the free and pinned layers further includes a second ferromagnetic layer and an insulating layer, such as a NOL, between the two ferromagnetic layers. The insulating layer causes twisted coupling between the two ferromagnetic layers, rotating the magnetization direction of one 90 degrees relative to the magnetization direction of the other.

Abstract: A memory cell structure. A first conductive line is cladded by at least two first ferromagnetic layers respectively having a first easy axis and a second easy axis, a nano oxide layer located between the first ferromagnetic layers, and a first pinned ferromagnetic layer. The first and second easy axes are 90 degree twisted-coupled with the first easy axis parallel to the length of the first conductive line and the second easy axis perpendicular to the length of the first conductive line. A storage device is adjacent to the first conductive line, receiving a magnetic field generated from a current flowing through the first conductive line.

Abstract: A circuit with an inter-module radiation interference shielding mechanism is disclosed. The circuit includes a circuit module producing a radiation field. At least one radiation shielding module is situated between the circuit module and another module that is vulnerable to the interference of the radiation field. The shielding module is substantially tangential to the radiation field.

Abstract: A magnetic random access memory device (MRAM) and the method for forming the same are disclosed. The MRAM has a magnetic tunnel junction (MTJ) device, a first write line, and a second write line orthogonal to the first write line, wherein at least one of the first and second write lines has a width narrower than that of the MTJ.

Abstract: A method of manufacturing a memory device is provided. The method includes forming an electrode over a substrate. The method also includes forming an opening in the electrode to provide a tapered electrode contact surface proximate the opening. The method further includes forming a phase change feature over the electrode and on the tapered electrode contact surface.

Abstract: A magnetic shielding device is provided for protecting at least one magnetically sensitive component on a substrate according to embodiments of the present invention. The device comprises a first shield having a top portion, and one or more side portions, wherein the top and side portions along with the substrate encloses the magnetic sensitive component within for protecting the same from an external magnetic field, and wherein the magnetic shielding device contains at least two magnetic shielding materials with one having a relatively higher magnetic permeability property but lower magnetic saturation property while the other having a relatively lower magnetic permeability property but higher magnetic saturation property.

Abstract: A new process and structure for a multi-sensing level magnetic random access memory (MRAM) cell having different magneto-resistance (MR) ratios includes an improved magnetic tunnel junction (MTJ) configuration. The MTJ configuration includes a first free layer proximate to a first tunneling barrier and a second free layer proximate to a second tunneling barrier and a pinned layer. The first free layer is sandwiched between the first and second tunneling layers. The first tunneling barrier has a MR ratio that differs from a MR ratio of the second tunneling barrier.

Abstract: A method of manufacturing a memory device including forming an electrode over a substrate, then forming a dielectric feature proximate a contact region of a sidewall of the electrode, and then forming a phase change feature proximate the contact region.

Abstract: A magnetic random access memory (MRAM) cell including an MRAM stack and a conductive line for carrying write current associated with the MRAM cell in a direction that is angularly offset from an easy axis of the MRAM stack by an acute angle, such as about 45 degrees.

Abstract: A method and system is disclosed for directing charged particles on predetermined areas on a target semiconductor substrate. After aligning a wafer mask with a semiconductor wafer, with the wafer mask having one or more mask patterns thereon, the charged particles are directed to pass through the mask patterns to land on one or more selected areas on the semiconductor wafer.

Abstract: A new capacitor device having two terminals is achieved. The device comprises a plurality of first conductive lines overlying a substrate. Each of the first conductive lines is connected to one of the capacitor device terminals. The adjacent first conductive lines are connected to opposite terminals. The first conductive lines comprise a plurality of conductive materials. A plurality of second conductive lines overlie the plurality of first conductive lines. Each of the second conductive lines is connected to one of the capacitive device terminals. Adjacent second conductive lines are connected to opposite terminals. Any second conductive line overlying any first conductive line is connected to an opposite terminal. The second conductive lines comprises a plurality of conductive materials. A first dielectric layer overlies the substrate and lies between the adjacent first conductive lines. A second dielectric layer lies between the first conductive lines and the second conductive lines.