Patent application number | Description | Published |
20110049456 | PHASE CHANGE STRUCTURE WITH COMPOSITE DOPING FOR PHASE CHANGE MEMORY - A memory device is described using a composite doped phase change material between a first electrode and a second electrode. A memory element of phase change material, such as a chalcogenide, is between the first and second electrodes and has an active region. The phase change material has a first dopant, such as silicon oxide, characterized by tending to segregate from the phase change material on grain boundaries in the active region, and has a second dopant, such as silicon, characterized by causing an increase in recrystallization temperature of, and/or suppressing void formation in, the phase change material in the active region. | 03-03-2011 |
20120193595 | COMPOSITE TARGET SPUTTERING FOR FORMING DOPED PHASE CHANGE MATERIALS - A layer of phase change material with silicon or another semiconductor, or a silicon-based or other semiconductor-based additive, is formed using a composite sputter target including the silicon or other semiconductor, and the phase change material. The concentration of silicon or other semiconductor is more than five times greater than the specified concentration of silicon or other semiconductor in the layer being formed. For silicon-based additive in GST-type phase change materials, sputter target may comprise more than 40 at % silicon. Silicon-based or other semiconductor-based additives can be formed using the composite sputter target with a flow of reactive gases, such as oxygen or nitrogen, in the sputter chamber during the deposition. | 08-02-2012 |
Patent application number | Description | Published |
20100091558 | Dielectric-Sandwiched Pillar Memory Device - A memory device includes bottom and top electrode structures and a memory cell therebetween. The memory cell comprises bottom and top memory elements and a dielectric element therebetween. A lower resistance conduction path is formed through the dielectric element. The dielectric element may have an outer edge and a central portion, the outer edge being thicker than the central portion. To make a memory device, an electrical pulse is applied through the memory cell to form a conduction path through the dielectric element. A passivation element may be formed by oxidizing the outer surface of the memory cell which may also enlarge the outer edge of the dielectric element. | 04-15-2010 |
20100177553 | REWRITABLE MEMORY DEVICE - Memory devices described herein are programmed and erased by physical segregation of an electrically insulating layer out of a memory material to establish a high resistance state, and by re-absorption of at least a portion of the electrically insulating layer into the memory material to establish a low resistance state. The physical mechanism of programming and erasing includes movement of structure vacancies to form voids, and/or segregation of doping material and bulk material, to create the electrically insulating layer consisting of voids and/or dielectric doping material along an inter-electrode current path between electrodes. | 07-15-2010 |
20110012083 | PHASE CHANGE MEMORY CELL STRUCTURE - A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface. | 01-20-2011 |
20110133150 | Phase Change Memory Cell with Filled Sidewall Memory Element and Method for Fabricating the Same - Memory cells are described along with methods for manufacturing. A memory cell described herein includes a bottom electrode, a top electrode overlying the bottom electrode, a via having a sidewall extending from a bottom electrode to a top electrode, and a memory element electrically coupling the bottom electrode to the top electrode. The memory element has an outer surface contacting a dielectric sidewall spacer that is on the sidewall of the via, and comprises a stem portion on the bottom electrode and a cup portion on the stem portion. A fill material is within an interior defined by an inner surface of the cup portion of the memory element. | 06-09-2011 |
20120187362 | Phase Change Memory Cell Structure - A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface. | 07-26-2012 |
Patent application number | Description | Published |
20090189138 | FILL-IN ETCHING FREE PORE DEVICE - A memory cell includes a memory cell layer with a first dielectric layer over a bottom electrode layer, a second dielectric layer over the first dielectric layer, and a top electrode over the second dielectric layer. The dielectric layers define a via having a first part bounded by the first electrode layer and the bottom electrode and a second part bounded by the second dielectric layer and the top electrode. A memory element is within the via and is in electrical contact with the top and bottom electrodes. The first and second parts of the via may comprise a constricted, energy-concentrating region and an enlarged region respectively. The constricted region may have a width smaller than the minimum feature size of the process used to form the enlarged region of the via. A method for manufacturing a memory cell is also disclosed. | 07-30-2009 |
20090212274 | PHASE CHANGE MEMORY RANDOM ACCESS DEVICE USING SINGLE-ELEMENT PHASE CHANGE MATERIAL - A phase change memory cell with a single element phase change thin film layer; and a first electrode and a second electrode coupled to the single element phase change thin film layer. A current flows from the first electrode to the single element phase change thin film layer, and through to the second electrode. The single element phase change thin film layer includes a single element phase change material. The single element phase change thin film layer can be less than 5 nanometers thick. The temperature of crystallization of the single element phase change material can be controlled by its thickness. In one embodiment, the single element phase change thin film layer is configured to be amorphous at room temperature (25 degrees Celsius). In one embodiment, the single element phase change thin film layer is comprised of Antimony (Sb). | 08-27-2009 |
20090279349 | PHASE CHANGE DEVICE HAVING TWO OR MORE SUBSTANTIAL AMORPHOUS REGIONS IN HIGH RESISTANCE STATE - Memory devices are described herein along with method for operating the memory device. A memory cell as described herein includes a first electrode and a second electrode. The memory cell also comprises phase change material having first and second active regions arranged in series along an inter-electrode current path between the first and second electrode. | 11-12-2009 |
20100084624 | Dielectric mesh isolated phase change structure for phase change memory - A method for manufacturing a memory device, and a resulting device, is described using silicon oxide doped chalcogenide material. A first electrode having a contact surface; a body of phase change memory material in a polycrystalline state including a portion in contact with the contact surface of the first electrode, and a second electrode in contact with the body of phase change material are formed. The process includes melting and cooling the phase change memory material one or more times within an active region in the body of phase change material without disturbing the polycrystalline state outside the active region. A mesh of silicon oxide in the active region with at least one domain of chalcogenide material results. Also, the grain size of the phase change material in the polycrystalline state outside the active region is small, resulting in a more uniform structure. | 04-08-2010 |
20100328996 | PHASE CHANGE MEMORY HAVING ONE OR MORE NON-CONSTANT DOPING PROFILES - A phase change memory device with a memory element including a basis phase change material, such as a chalcogenide, and one or more additives, where the additive or additives have a non-constant concentration profile along an inter-electrode current path through a memory element. The use of “non-constant” concentration profiles for additives enables doping the different zones with different materials and concentrations, according to the different crystallographic, thermal and electrical conditions, and different phase transition conditions. | 12-30-2010 |
20120309159 | METHOD TO SELECTIVELY GROW PHASE CHANGE MATERIAL INSIDE A VIA HOLE - An example embodiment is a method for filling a via hole with phase change material. The method steps include forming a bottom electrode in a substrate, depositing a dielectric layer above the bottom electrode, and forming a via hole within the dielectric layer down to a top surface of the bottom electrode. The substrate is heated to a reaction temperature and a first phase change material precursor is deposited within the via hole. The first precursor is configured to decompose on the top surface of the bottom electrode and chemisorb on a top surface of the dielectric layer at the reaction temperature. A second precursor is deposited within the via hole after the first precursor at least partially decomposes on the top surface of the bottom electrode. | 12-06-2012 |
Patent application number | Description | Published |
20090014704 | CURRENT CONSTRICTING PHASE CHANGE MEMORY ELEMENT STRUCTURE - A layer of nanopaiticles having a dimension on the order of 10 nm is employed to form a current constricting layer or as a hardmask for forming a current constricting layer from an underlying insulator layer. The nanoparticles are preferably self-aligning and/or self-planarizing on the underlying surface. The current constricting layer may be formed within a bottom conductive plate, within a phase change material layer, within a top conductive plate, or within a tapered liner between a tapered via sidewall and a via plug contains either a phase change material or a top conductive material. The current density of the local structure around the current constricting layer is higher than the surrounding area, thus allowing local temperature to rise higher than surrounding material. The total current required to program the phase change memory device, and consequently the size of a programming transistor, is reduced due to the current constricting layer. | 01-15-2009 |
20100193763 | CURRENT CONSTRICTING PHASE CHANGE MEMORY ELEMENT STRUCTURE - A layer of nanoparticles having a dimension on the order of 10 nm is employed to form a current constricting layer or as a hardmask for forming a current constricting layer from an underlying insulator layer. The nanoparticles are preferably self-aligning and/or self-planarizing on the underlying surface. The current constricting layer may be formed within a bottom conductive plate, within a phase change material layer, within a top conductive plate, or within a tapered liner between a tapered via sidewall and a via plug contains either a phase change material or a top conductive material. The current density of the local structure around the current constricting layer is higher than the surrounding area, thus allowing local temperature to rise higher than surrounding material. The total current required to program the phase change memory device, and consequently the size of a programming transistor, is reduced due to the current constricting layer. | 08-05-2010 |