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| 20100197119 | Resistor Random Access Memory Cell Device - A memory cell device has a bottom electrode and a top electrode, a plug of memory material in contact with the bottom electrode, and a cup-shaped conductive member having a rim that contacts the top electrode and an opening in the bottom that contacts the memory material. Accordingly, the conductive path in the memory cells passes from the top electrode through the conductive cup-shaped member, and through the plug of phase change material to the bottom electrode. Also, methods for making the memory cell device include steps of forming a bottom electrode island including an insulative element and a stop element over a bottom electrode, forming a separation layer surrounding the island, removing the stop element to form a hole over the insulative element in the separation layer, forming a conductive film in the hole and an insulative liner over conductive film, etching to form a cup-shaped conductive film having a rim and to form an opening through the insulative liner and the bottom of the cup-shaped conductive film to the surface of the bottom electrode, forming a plug of phase change memory material in the opening, and forming a top electrode in contact with the rim of the cup-shaped conductive film. | 08-05-2010 |
| 20100216279 | METHOD OF A MULTI-LEVEL CELL RESISTANCE RANDOM ACCESS MEMORY WITH METAL OXIDES - A method and structure of a bistable resistance random access memory comprise a plurality of programmable resistance random access memory cells where each programmable resistance random access memory cell includes multiple memory members for performing multiple bits for each memory cell. The bistable RRAM includes a first resistance random access member connected to a second resistance random access member through interconnect metal liners and metal oxide strips. The first resistance random access member has a first resistance value Ra, which is determined from the thickness of the first resistance random access member based on the deposition of the first resistance random access member. The second resistance random access member has a second resistance value Rb, which is determined from the thickness of the second resistance random access member based on the deposition of the second resistance random access member. | 08-26-2010 |
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| 20080266940 | Air Cell Thermal Isolation for a Memory Array Formed of a Programmable Resistive Material - A memory device includes, a first electrode element, generally planar in form, having an inner contact surface. Then there is a cylindrical cap layer, spaced from the first electrode element, and a phase change element having contact surfaces in contact with the first electrode contact surface and the cap layer, in which the lateral dimension of the phase change element is less than that of the first electrode element and the cylindrical cap layer. A second electrode element extends through the cap layer to make contact with the phase change element. Side walls aligned with the cap layer, composed of dielectric fill material, extend between the first electrode elements and the cap layer, such that the phase change element, the contact surface of the first electrode element and the side walls define a gas-filled thermal isolation cell adjacent the phase change element. | 10-30-2008 |
| 20090020740 | RESISTIVE MEMORY STRUCTURE WITH BUFFER LAYER - A memory device comprises first and second electrodes with a memory element and a buffer layer located between and electrically coupled to them. The memory element comprises one or more metal oxygen compounds. The buffer layer comprises at least one of an oxide and a nitride. Another memory device comprises first and second electrodes with a memory element and a buffer layer, having a thickness of less than 50 Å, located between and electrically coupled to them. The memory comprises one or more metal oxygen compounds. An example of a method of fabricating a memory device includes forming first and second electrodes. A memory, located between and electrically coupled to the first and the second electrodes, is formed; the memory comprises one or more metal oxygen compounds and the buffer layer comprises at least one of an oxide and a nitride. | 01-22-2009 |
| 20090032793 | Resistor Random Access Memory Structure Having a Defined Small Area of Electrical Contact - A memory cell device, of the type that includes a memory material switchable between electrical property states by application of energy, includes first and second electrodes, a plug of memory material (such as phase change material) which is in electrical contact with the second electrode, and an electrically conductive film which is supported by a dielectric form and which is in electrical contact with the first electrode and with the memory material plug. The dielectric form is wider near the first electrode, and is narrower near the phase change plug. The area of contact of the conductive film with the phase change plug is defined in part by the geometry of the dielectric form over which the conductive film is formed. Also, methods for making the device include steps of constructing a dielectric form over a first electrode, and forming a conductive film over the dielectric form. | 02-05-2009 |
| 20090096017 | STACKED THIN FILM TRANSISTOR, NON-VOLATILE MEMORY DEVICES AND METHODS FOR FABRICATING THE SAME - A manufacturing method for stacked, non-volatile memory devices provides a plurality of bitline layers and wordline layers with charge trapping structures. The bitline layers have a plurality of bitlines formed on an insulating layer, such as silicon on insulator technologies. The wordline layers are patterned with respective pluralities of wordlines and charge trapping structures orthogonal to the bitlines. | 04-16-2009 |
| 20090101883 | Method for manufacturing a resistor random access memory with a self-aligned air gap insulator - A memory device including a programmable resistive memory material is described along with methods for manufacturing the memory device. A memory device disclosed herein includes top and bottom electrodes and a multilayer stack disposed between the top and bottom electrodes. The multilayer stack includes a memory element comprising programmable resistive memory material and has a sidewall surface. An air gap is adjacent to the sidewall surface and self-aligned to the memory element. | 04-23-2009 |
| 20100054014 | HIGH DENSITY RESISTANCE BASED SEMICONDUCTOR DEVICE - Memory devices are described along with methods for manufacturing. A memory device as described herein includes a plurality of memory cells located between word lines and bit lines. Each memory cell comprises a diode and a plurality of memory elements each comprising one or more metal-oxygen compounds, the diode and the plurality of memory elements arranged in electrical series along a current path between a corresponding word line and a corresponding bit line. | 03-04-2010 |
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| 20090020746 | SELF-ALIGNED STRUCTURE AND METHOD FOR CONFINING A MELTING POINT IN A RESISTOR RANDOM ACCESS MEMORY - A process in the manufacturing of a resistor random access memory with a confined melting area for switching a phase change in the programmable resistive memory. The process initially formed a pillar comprising a substrate body, a first conductive material overlying the substrate body, a programmable resistive memory material overlying the first conductive material, a high selective material overlying the programmable resistive memory material, and a silicon nitride material overlying the high selective material. The high selective material in the pillar is isotropically etched on both sides of the high selective material to create a void on each side of the high selective material with a reduced length. A programmable resistive memory material is deposited in a confined area previously occupied by the reduced length of the poly, and the programmable resistive memory material is deposited into an area previously occupied by the silicon nitride material. | 01-22-2009 |
| 20090141543 | MAGNETIC RANDOM ACCESS MEMORY, MANUFACTURING METHOD AND PROGRAMMING METHOD THEREOF - A magnetic random access memory (MRAM) and a manufacturing method and a programming method thereof are provided. The magnetic random access memory comprises a first magnetic tunnel junction structure and a second magnetic tunnel junction structure The second magnetic tunnel junction structure is electrically connected with the first magnetic tunnel junction structure, and the volume of the second magnetic tunnel junction structure is smaller than that of the first magnetic tunnel junction structure. | 06-04-2009 |
| 20090236743 | Programmable Resistive RAM and Manufacturing Method - 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. | 09-24-2009 |
| 20100001330 | SEMICONDUCTOR DEVICE, DATA ELEMENT THEREOF AND METHOD OF FABRICATING THE SAME - A method of fabricating a semiconductor device is provided. The method comprises: (a) providing a first and a second conductor; (b) providing a conductive layer; (c) forming a part of the conductive layer into a data storage layer by a plasma oxidation process, wherein the data storage layer is positioned between the first and the second conductor. | 01-07-2010 |
| 20100015757 | BRIDGE RESISTANCE RANDOM ACCESS MEMORY DEVICE AND METHOD WITH A SINGULAR CONTACT STRUCTURE - 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. | 01-21-2010 |
