Patent application number | Description | Published |
20100055830 | I-SHAPED PHASE CHANGE MEMORY CELL - A memory device includes two electrodes, vertically separated and having mutually opposed contact surfaces, between which lies a phase change cell. The phase change cell includes an upper phase change member, having a contact surface in electrical contact with the first electrode; a lower phase change member, having a contact surface in electrical contact with the second electrode; and a kernel member disposed between and in electrical contact with the upper and lower phase change members. The phase change cell is formed of material having at least two solid phases, and the lateral extent of the upper and lower phase change members is substantially greater than that of the kernel member. An intermediate insulating layer is disposed between the upper and lower phase change members adjacent to the kernel member. | 03-04-2010 |
20100144128 | Phase Change Memory Cell and Manufacturing Method - A phase change memory cell includes first and second electrodes electrically coupled by a phase change element. At least a section of the phase change element comprises a higher reset transition temperature portion and a lower reset transition temperature portion. The lower reset transition temperature portion comprises a phase change region which can be transitioned, by the passage of electrical current therethrough, from generally crystalline to generally amorphous states at a lower temperature than the higher reset transition temperature portion. The phase change element may comprise an outer, generally tubular, higher reset transition temperature portion surrounding an inner, lower reset transition temperature portion. | 06-10-2010 |
20100291747 | Phase Change Memory Device and Manufacturing Method - A phase change memory device comprises a photolithographically formed phase change memory cell having first and second electrodes and a phase change element positioned between and electrically coupling the opposed contact elements of the electrodes to one another. The phase change element has a width, a length and a thickness. The length, the thickness and the width are less than a minimum photolithographic feature size of the process used to form the phase change memory cell. The size of the photoresist masks used in forming the memory cell may be reduced so that the length and the width of the phase change element are each less than the minimum photolithographic feature size. | 11-18-2010 |
20100301304 | BURIED SILICIDE STRUCTURE AND METHOD FOR MAKING - Methods for manufacturing buried silicide lines are described herein, along with high density stacked memory structures. A method for manufacturing an integrated circuit as described herein includes forming a semiconductor body comprising silicon. A plurality of trenches are formed in the semiconductor body to define semiconductor lines comprising silicon between adjacent trenches, the semiconductor lines having sidewalls. A silicide precursor is deposited within the trenches to contact the sidewalls of the semiconductor lines, and a portion of the silicide precursor is removed to expose upper portions of the sidewalls and leave remaining strips of silicide precursor along the sidewalls. Silicide conductors are then formed by inducing reaction of the strips of silicide with the silicon of the semiconductor lines. | 12-02-2010 |
20110006279 | PHASE CHANGE MEMORY - A phase change memory (PCM) is provided which includes a substrate, a plurality of bottom electrodes, a plurality of top electrodes, a plurality of phase change materials, and a plurality of thermal disturbance-preventing parts. The bottom electrodes are disposed in the substrate, and the top electrodes are disposed on the substrate. The phase change (PC) materials are disposed between the top and bottom electrodes, and each of the PC materials is conducted with one of the top electrodes and one of the bottom electrodes. The thermal disturbance-preventing parts are utilized to reduce the effect of thermal disturbance upon the PCM. | 01-13-2011 |
20110012079 | THERMAL PROTECT PCRAM STRUCTURE AND METHODS FOR MAKING - A memory cell as described herein includes a conductive contact and a memory element comprising programmable resistance memory material overlying the conductive contact. An insulator element extends from the conductive contact into the memory element, the insulator element having proximal and distal ends and an inside surface defining an interior. The proximal end is adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end. The memory element is within the interior extending downwardly from the distal end to contact a top surface of the bottom electrode at a first contact surface. A top electrode can be separated from the distal end of the insulator element by the memory element and contact the memory element at a second contact surface having a surface area greater than that of the first contact surface. | 01-20-2011 |
20110044097 | PHASE CHANGE MEMORY AND OPERATION METHOD OF THE SAME - An operation method of phase change memory (PCM) is provided. The operation method includes applying a RESET pulse to a phase change material of the PCM, wherein the RESET pulse has a profile with a first tail such that a plurality of seeds are formed in the phase change material. Due to the design of the RESET pulse in the operation method, it can speed up the crystal process. | 02-24-2011 |
20120077309 | THERMALLY STABILIZED ELECTRODE STRUCTURE - Memory devices and methods for manufacturing are described herein. A memory device as described herein includes a first electrode layer, a second electrode layer, and a thermal isolation structure including a layer of thermal isolation material between the first and second electrode layers. The first and second electrode layers and the thermal isolation structure define a multi-layer stack having a sidewall. A sidewall conductor layer including a sidewall conductor material is on the sidewall of the multi-layer stack. The sidewall conductor material has an electrical conductivity greater than that of the thermal isolation material. A memory element including memory material is on and in contact with the second electrode layer. | 03-29-2012 |
20120182802 | Memory Architecture of 3D Array With Improved Uniformity of Bit Line Capacitances - A 3D integrated circuit memory array has a plurality of plane positions. Multiple bit line structures have a multiple sequences of multiple plane positions. Each sequence characterizes an order in which a bit line structure couples the plane positions to bit lines. Each bit line is coupled to at least two different plane positions to access memory cells at two or more different plane positions. | 07-19-2012 |
20120182806 | Memory Architecture of 3D Array With Alternating Memory String Orientation and String Select Structures - A 3D memory device includes a plurality of ridge-shaped stacks, in the form of multiple strips of conductive material separated by insulating material, arranged as bit lines which can be coupled through decoding circuits to sense amplifiers. Diodes are connected to the bit lines at either the string select of common source select ends of the strings. The strips of conductive material have side surfaces on the sides of the ridge-shaped stacks. A plurality of word lines, which can be coupled to row decoders, extends orthogonally over the plurality of ridge-shaped stacks. Memory elements lie in a multi-layer array of interface regions at cross-points between side surfaces of the semiconductor strips on the stacks and the word lines. | 07-19-2012 |
20130075802 | CONTACT ARCHITECTURE FOR 3D MEMORY ARRAY - A vertical interconnect architecture for a three-dimensional (3D) memory device suitable for low cost, high yield manufacturing is described. Conductive lines (e.g. word lines) for the 3D memory array, and contact pads for vertical connectors used for couple the array to decoding circuitry and the like, are formed as parts of the same patterned level of material. The same material layer can be used to form the contact pads and the conductive access lines by an etch process using a single mask. By forming the contact pads concurrently with the conductive lines, the patterned material of the contact pads can protect underlying circuit elements which could otherwise be damaged during patterning of the conductive lines. | 03-28-2013 |
20130119455 | NAND FLASH WITH NON-TRAPPING SWITCH TRANSISTORS - A manufacturing method for a memory array includes first forming a multilayer stack of dielectric material on a plurality of semiconductor strips, and then exposing the multilayer stack in switch transistor regions. The multilayer stacks exposed in the switch transistor regions are processed to form gate dielectric structures that are different than the dielectric charge trapping structures. Word lines and select lines are then formed. A 3D array of dielectric charge trapping memory cells includes stacks of NAND strings of memory cells. A plurality of switch transistors are coupled to the NAND strings, the switch transistors including gate dielectric structures wherein the gate dielectric structures are different than the dielectric charge trapping structures. | 05-16-2013 |
20130153846 | THREE DIMENSIONAL MEMORY ARRAY ADJACENT TO TRENCH SIDEWALLS - A self-aligning stacked memory cell array structure and method for fabricating such structure. The memory cell array includes a stack of memory cells disposed adjacent to opposing sides of a conductive line that is formed within a trench. The memory cells are stacked such that the memory element surface of each memory cell forms a portion of the sidewall of the conductive line. The conductive line is formed within the trench such that electrical contact is made across the entire memory element surface of each memory cell. Such structure and method for making such structure is a self-aligning process that does not require the use of any additional masks. | 06-20-2013 |
20140054784 | Integrated Circuit Connector Access Region and Method for Making - A connector access region of an integrated circuit device includes a set of parallel conductors, extending in a first direction, and interlayer connectors. The conductors comprise a set of electrically conductive contact areas on different conductors which define a contact plane with the conductors extending below the contact plane. A set of the contact areas define a line at an oblique angle, such as less than 45° or 5° to 27°, to the first direction. The interlayer connectors are in electrical contact with the contact areas and extend above the contact plane. At least some of the interlayer connectors overlie but are electrically isolated from the electrical conductors adjacent to the contact areas with which the interlayer connectors are in electrical contact. The set of parallel conductors may include a set of electrically conductive layers with the contact plane being generally perpendicular to the electrically conductive layers. | 02-27-2014 |
20140177311 | MEMORY DEVICE STRUCTURE WITH DECODERS IN A DEVICE LEVEL SEPARATE FROM THE ARRAY LEVEL - A memory device structure and method of fabricating the memory device structure is described. The memory device structure has a memory array disposed in a array level and peripheral circuitry, including decoders and other peripheral circuitry, disposed in a device level. The array of memory cells has a perimeter that defines a cylinder that extends above and beneath the array of memory cells. The decoders and the other peripheral circuitry or at least part of the decoders and the other peripheral circuitry are disposed within the cylinder in the device level. The memory device structure also includes a plurality of pads in a pad level. A first plurality of inter-level conductive lines electrically couples the decoders to the bit lines and word lines in the array of memory cells. | 06-26-2014 |
20140193973 | METHOD FOR FORMING INTERLAYER CONNECTORS TO A STACK OF CONDUCTIVE LAYERS - A method forms interlayer connectors extending to conductive layers of a stack of W conductive layers interleaved with dielectric layers. The stack is etched to expose landing areas at W−1 conductive layers using a set of M etch masks. For each etch mask m, m going from 0 to M−1, there is a first etching step, at least one mask trimming step, and a subsequent etching step following each trimming step. The etch mask may cover N | 07-10-2014 |
20150055414 | MEMORY DEVICE STRUCTURE WITH PAGE BUFFERS IN A PAGE-BUFFER LEVEL SEPARATE FROM THE ARRAY LEVEL - A structure of a memory device and a method for making the memory device structure are described. The memory device includes an array of memory cells in an array level die. The array comprises a plurality of sub-arrays. Each of the sub-arrays comprises respective data lines. The memory device also includes page buffers for corresponding sub-arrays in a page-buffer level die. The memory device also includes inter-die connections that are configured to electrically couple the page buffers in the page-buffer level die to data lines of corresponding sub-arrays in the array level die. | 02-26-2015 |
20150085579 | CONTACT STRUCTURE AND FORMING METHOD - Vias are formed within a stack of alternating active and insulating layers by forming a first sub stack, a second sub stack over the first sub stack, a first buffer layer therebetween and a second buffer layer under the first sub stack. An upper layer of the first sub stack is exposed through a set of vias by first and second etching processes. The first etching process forms a first set of etch vias through the second sub stack and stops at or in the first buffer layer. The second etching process etches through the first buffer layer to the upper layer of the first sub stack. A third etching process etches through the first set of etch vias, through the first sub stack and stops at or in the second buffer layer. A fourth etching process and etches through the second buffer layer. | 03-26-2015 |