Abstract: A pillar-type phase change memory element comprises first and second electrode elements and a phase change element therebetween. A second electrode material and a chlorine-sensitive phase change material are selected. A first electrode element is formed. The phase change material is deposited on the first electrode element and the second electrode material is deposited on the phase change material. The second electrode material and the phase change material are etched without the use of chlorine to form a second electrode element and a phase change element. The second electrode material selecting step, the phase change material selecting step and the etching procedure selecting step are carried out so that the phase change element is not undercut relative to the second electrode element during etching.

Abstract: A memory device has a sidewall insulating member with a sidewall insulating member length according to a first spacer layer thickness. A first electrode formed from a second spacer layer having a first electrode length according to a thickness of a second spacer layer and a second electrode formed from the second spacer layer having a second electrode length according to the thickness of the second spacer layer are formed on sidewalls of the sidewall insulating member. A bridge of memory material having a bridge width extends from a top surface of the first electrode to a top surface of the second electrode across a top surface of the sidewall insulating member, wherein the bridge comprises memory material.

Abstract: A magnetic random access memory (MRAM) cell comprises a MRAM device and a single crystal self-aligned diode. The MRAM device and the single crystal self-aligned diode are connected through a contact. Only one metal line is positioned above the MRAM device of the MRAM cell. A first and second spacers positioned adjacent to the opposite sidewalls of the contact define the size of the single crystal self-aligned diode. A first and second metal silicide lines are positioned adjacent to the first and second spacers, respectively. The single crystal self-aligned diode, defined in a silicon substrate, includes a bottom implant (BI) region and a contact implant (CI) region. The CI region is surrounded by the BI region except for a side of the CI region that aligns the surface of the silicon substrate. A fabrication method, a read method, two programming methods for the MRAM cell are also disclosed.

Abstract: A resistance random access memory in a bridge structure is disclosed that comprises a contact structure where first and second electrodes are located within the contact structure. The first electrode has a circumferential extending shape, such as an annular shape, surrounding an inner wall of the contact structure. The second electrode is located within an interior of the circumferential extending shape and separated from the first electrode by an insulating material. A resistance memory bridge is in contact with an edge surface of the first and second electrodes. The first electrode in the contact structure is connected to a transistor and the second electrode in the contact structure is connected to a bit line. A bit line is connected to the second electrode by a self-aligning process.

Abstract: Structures and methods to form a bistable resistive random access memory for reducing the amount of heat dissipation from electrodes by confining a heating region in the memory cell device are described. The heating region is confined in a kernel comprising a programmable resistive memory material that is in contact with an upper programmable resistive memory member and a lower programmable resistive memory member. The lower programmable resistive member has sides that align with sides of a bottom electrode comprising a tungsten plug. The lower programmable resistive member and the bottom electrode function a first conductor so that the amount of heat dissipation from the first conductor is reduced. The upper programmable resistive memory material and a top electrode function as a second conductor so that the amount of heat dissipation from the second conductor is reduced.

Abstract: A magnetic memory device comprises a magnetic memory cell that includes a pinned layer and a free layer separated from the pinned layer by an insulating layer. The magnetic memory device also comprises a thermal plate in contact with the free layer. The magnetic memory device can be configured so that a first current flows through the thermal plate heating the thermal plate. The magnetic behavior of the free layer can be altered due to the heating caused by the first current, making it easier to switch the orientation and magnetization of the free layer. A second current can then flow through a bit line near the free layer generating a magnetic field sufficient to switch the orientation of magnetization of the free layer.

Abstract: A memory device includes first and second electrodes separated by an insulating member comprising upwardly and inwardly tapering surfaces connected by a surface segment. A bridge, comprising memory material, such as a phase change material, switchable between electrical property states by the application of energy, is positioned across the surface segment and in contact with the electrodes to define an inter-electrode path defined at least in part by the length of the surface segment. According to a method for making a memory cell device, the tapering surfaces may be created by depositing a dielectric material cap using a high density plasma (HDP) deposition procedure. The electrodes and the dielectric material cap may he planarized to create the surface segment on the dielectric material. At least one of the dielectric material depositing step and the planarizing step may be controlled so that the length of the surface and segment is within a chosen dimensional range, such as between 10 nm and 100 nm.

Abstract: Memory cells which include a semiconductor substrate having a source region and a drain region separated by a channel region; a charge-trapping structure disposed above the channel region of the semiconductor substrate; a first gate disposed above the charge-trapping structure and proximate to the source region; and a second gate disposed above the charge-trapping structure and proximate to the drain region; where the first gate and the second gate are separated by a first nanospace are provided, along with arrays including a plurality of such cells, methods of manufacturing such cells and methods of operating such cells.

Abstract: An array of memory cells is arranged in columns and one or more rows on a semiconductor substrate. Each cell has a source, a drain, a first gate and a second gate. The array includes a plurality of gate control lines, each of which corresponds to one of the columns of the memory cells, where each control line connects to the first gate of the memory cell in the corresponding column in each of the rows; and one or more word lines, each of which corresponds to one of the rows of the memory cells, where each word line connects to the second gate of each of the cells in the corresponding row.

Abstract: An invention is provided for a low write current MRAM. Each MRAM cell includes a word line and a bit line. A magnetic device is disposed at the intersection of the word line and the bit line. Disposed at either end of the magnetic device is a writing magnet. The pair of writing magnets switches a magnetic alignment of the magnetic device during a write operation. In aspect, the pair of writing magnets and the magnetic device can be aligned along a long axis of the memory cell, which generally is not aligned with either the word line or the bit line.

Abstract: An MRAM cell comprises a magnetic metal layer and a magnetic sensing device in close proximity to the magnetic metal layer. One end of the magnetic metal layer is coupled with a word line transistor and a diode is included and configured to couple the magnetic sensing device to a bit line. The magnetic metal layer can be used to both program and read the cell, eliminating the need for a second current line in the cell.

Abstract: Programmable resistive RAM cells have a resistance that depends on the size of the contacts. Manufacturing methods and integrated circuits for lowered contact resistance are disclosed that have contacts of reduced size.

Abstract: An MRAM device comprises a plurality of MRAM structures, each MRAM structure comprising a magnetoresistive memory cell in close proximity to a high permeability conductive line and a single transistor configured to access the magnetoresistive memory cell for both read and write operations. The high permeability conductive line acts a current path for both read and write operations, thereby reducing the number of metal bit lines.

Abstract: Roughly described, a magnetic structure includes an electrically conductive path for carrying current flow, a soft magnetic material with high permeability value in magnetic communication with the current flow so that it can be magnetized in either of two directions, and a magnetic device such as a magnetic random access memory cell, having an active layer that is quantum mechanically or magnetostatically coupled to the soft magnetic material. The soft magnetic material acts as an intermediary between the magnetic induction of the current flow and the magnetization of the active layer of the magnetic device to reduce the writing current.

Abstract: Programmable resistive RAM cells have a resistance that depends on the size of the programmable resistive elements. Manufacturing methods and integrated circuits for programmable resistive elements with uniform resistance are disclosed that have a cross-section of reduced size compared to the cross-section of the interlayer contacts.

Abstract: A method of fabricating a sub-feature size pillar structure on an integrated circuit. The process first provides a substrate having formed thereon a phase change layer, an electrode layer and a hard-mask layer. Then there is formed a feature-size hard-mask, by lithographically patterning, etching and stripping a photoresist layer, followed by trimming the hard-mask to a selected sub-feature size, wherein the trimming step is highly selective between the electrode and phase change material layers and the hard-mask. The final steps are trimming the electrode and phase change layers to the size of the hard-mask and removing the hard-mask.

Abstract: Integrated circuit nonvolatile memory uses programmable resistive elements. In some examples, conductive structures such as electrodes are prepared, and the programmable resistive elements are laid upon the prepared electrodes. This prevents contamination of the programmable resistive elements from previous fabrication steps.

Abstract: A non-volatile method with a self-aligned RRAM element. The method includes a lower electrode element, generally planar in form, having an inner contact surface. At the top of the device is a upper electrode element, spaced from the lower electrode element. A containment structure extends between the upper electrode element and the lower electrode element, and this element includes a sidewall spacer element having an inner surface defining a generally funnel-shaped central cavity, terminating at a terminal edge to define a central aperture; and a spandrel element positioned between the sidewall spacer element and the lower electrode, having an inner surface defining a thermal isolation cell, the spandrel inner walls being spaced radially outward from the sidewall spacer terminal edge, such that the sidewall spacer terminal edge projects radially inward from the spandrel element inner surface.

Abstract: A protective layer is deposited on a chalcogenide layer and a patterned photoresist layer is formed on the protective layer. The patterned photoresist layer and the protective layer are etched to form openings therethrough to the chalcogenide layer to create etched photoresist and etched protective layers. The etched photoresist layer is removed leaving at least a portion of the etched protective layer. The chalcogenide layer is etched through the openings in the etched protective layer.

Abstract: A method for manufacturing a phase change memory device comprises forming an electrode layer. Electrodes are made in the electrode layer using conductor fill techniques that are also used inter-layer conductors for metallization layers, in order to improve process scaling with shrinking critical dimensions for metallization layers. The electrode layer is made by forming a multi-layer dielectric layer on a substrate, etching the multi-layer dielectric layer to form vias for electrode members contacting circuitry below, forming insulating spacers on the vias, etching through a top layer in the multi-layer dielectric layer to form trenches between the insulating spacers for electrode members contacting circuitry above, filling the vias and trenches with a conductive material using the metallization process. Thin film bridges of memory material are formed over the electrode layer.