Patent application number | Description | Published |
20100117069 | OPTIMIZED ELECTRODES FOR RE-RAM - Optimized electrodes for ReRAM memory cells and methods for forming the same are discloses. One aspect comprises forming a first electrode, forming a state change element in contact with the first electrode, treating the state change element, and forming a second electrode. Treating the state change element increases the barrier height at the interface between the second electrode and the state change element. Another aspect comprises forming a first electrode in a manner to deliberately establish a certain degree of amorphization in the first electrode, forming a state change element in contact with the first electrode. The degree of amorphization of the first electrode is either at least as great as the degree of amorphization of the state change element or no more than 5 percent less than the degree of amorphization of the state change element. | 05-13-2010 |
20110014771 | Method of making damascene diodes using selective etching methods - A method of making a semiconductor device includes providing an insulating layer containing a plurality of openings, forming a first conductivity type semiconductor layer in the plurality of openings, forming a second conductivity type semiconductor layer over the first conductivity type semiconductor layer in the plurality of openings, and selectively etching the second conductivity type semiconductor layer using an upper surface of the first conductivity type semiconductor layer as a stop to form a recess in the plurality of openings. | 01-20-2011 |
20110014779 | Method of making damascene diodes using sacrificial material - A method of making a semiconductor device includes forming a first layer comprising a seed material over an underlying layer, forming a second layer comprising a sacrificial material over the first layer, the sacrificial material being different from the seed material, patterning the first layer and the second layer into a plurality of separate features, forming an insulating filling material between the plurality of the separate features, removing the sacrificial material from the separate features to form a plurality of openings in the insulating filling material such that the seed material is exposed in the plurality of openings, and growing a semiconductor material on the exposed seed material in the plurality of openings. | 01-20-2011 |
20110227020 | BOTTOM ELECTRODES FOR USE WITH METAL OXIDE RESISTIVITY SWITCHING LAYERS - In a first aspect, a metal-insulator-metal (MIM) stack is provided that includes (1) a first conductive layer comprising a silicon-germanium (SiGe) alloy; (2) a resistivity-switching layer comprising a metal oxide layer formed above the first conductive layer; and (3) a second conductive layer formed above the resistivity-switching layer. A memory cell may be formed from the MIM stack. Numerous other aspects are provided. | 09-22-2011 |
20110227028 | BOTTOM ELECTRODES FOR USE WITH METAL OXIDE RESISTIVITY SWITCHING LAYERS - In a first aspect, an MIM stack is provided that includes (1) a first conductive layer comprising a first metal-silicide layer and a second metal-silicide layer; (2) a resistivity-switching layer comprising a metal oxide layer formed above the first conductive layer; and (3) a second conductive layer formed above the resistivity-switching layer. A memory cell may be formed from the MIM stack. Numerous other aspects are provided. | 09-22-2011 |
20110260290 | MEMORY CELL THAT INCLUDES A CARBON-BASED MEMORY ELEMENT AND METHODS OF FORMING THE SAME - In a first aspect, a memory cell is provided, the memory cell including: (a) a first conducting layer formed above a substrate; (b) a second conducting layer formed above the first conducting layer; (c) a structure formed between the first and second conducting layers, wherein the structure includes a sidewall that defines an opening extending between the first and second conducting layers, and wherein the structure is comprised of a material that facilitates selective, directional growth of carbon nano-tubes; and (d) a carbon-based switching layer that includes carbon nano-tubes formed on the sidewall of the structure. Numerous other aspects are provided. | 10-27-2011 |
20110310653 | Memory Cell With Resistance-Switching Layers - A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME) in series with a steering element. The RSME has first and second resistance-switching layers on either side of a conductive intermediate layer, and first and second electrodes at either end of the RSME. The first and second resistance-switching layers can both have a bipolar or unipolar switching characteristic. In a set or reset operation of the memory cell, an electric field is applied across the first and second electrodes. An ionic current flows in the resistance-switching layers, contributing to a switching mechanism. An electron flow, which does not contribute to the switching mechanism, is reduced due to scattering by the conductive intermediate layer, to avoid damage to the steering element. Particular materials and combinations of materials for the different layers of the RSME are provided. | 12-22-2011 |
20110310655 | Composition Of Memory Cell With Resistance-Switching Layers - A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME) in series with a steering element. The RSME has first and second resistance-switching layers on either side of a conductive intermediate layer, and first and second electrodes at either end of the RSME. The first and second resistance-switching layers can both have a bipolar or unipolar switching characteristic. In a set or reset operation of the memory cell, an ionic current flows in the resistance-switching layers, contributing to a switching mechanism. An electron flow, which does not contribute to the switching mechanism, is reduced due to scattering by the conductive intermediate layer, to avoid damage to the steering element. Particular materials and combinations of materials for the different layers of the RSME are provided. | 12-22-2011 |
20120001150 | MEMORY CELL THAT EMPLOYS A SELECTIVELY FABRICATED CARBON NANO-TUBE REVERSIBLE RESISTANCE-SWITCHING ELEMENT AND METHODS OF FORMING THE SAME - In some aspects, a method of fabricating a memory cell is provided that includes fabricating a steering element above a substrate, and fabricating a reversible-resistance switching element coupled to the steering element by selectively fabricating carbon nano-tube (“CNT”) material above the substrate, wherein the CNT material comprises a single CNT. Numerous other aspects are provided. | 01-05-2012 |
20120091413 | Three Dimensional Horizontal Diode Non-Volatile Memory Array and Method of Making Thereof - A non-volatile memory device contains a three dimensional stack of horizontal diodes located in a trench in an insulating material, a plurality of storage elements, a plurality of word lines extending substantially vertically, and a plurality of bit lines. Each of the plurality of bit lines has a first portion that extends up along at least one side of the trench and a second portion that extends substantially horizontally through the three dimensional stack of the horizontal diodes. Each of the horizontal diodes is a steering element of a respective non-volatile memory cell of the non-volatile memory device, and each of the plurality of storage elements is located adjacent to a respective steering element. | 04-19-2012 |
20130126821 | BOTTOM ELECTRODES FOR USE WITH METAL OXIDE RESISTIVITY SWITCHING LAYERS - In a first aspect, a metal-insulator-metal (“MIM”) stack is provided that includes a first conductive layer, a resistivity-switching layer having a metal oxide layer formed above the first conductive layer, a material layer between the first conductive layer and the resistivity-switching layer, and a second conductive layer above the resistivity-switching layer. The first conductive layer includes a multi-layer metal-silicide stack, and the material layer has a Gibbs free energy of formation per O between about −3 and −6 eV. A memory cell may be formed from the MIM stack. Numerous other aspects are provided. | 05-23-2013 |
20130248974 | COMPACT THREE DIMENSIONAL VERTICAL NAND AND METHOD OF MAKING THEREOF - A NAND device has at least a 3×3 array of vertical NAND strings in which the control gate electrodes are continuous in the array and do not have an air gap or a dielectric filled trench in the array. The NAND device is formed by first forming a lower select gate level having separated lower select gates, then forming plural memory device levels containing a plurality of NAND string portions, and then forming an upper select gate level over the memory device levels having separated upper select gates. | 09-26-2013 |
20140008714 | Three Dimensional NAND Device and Method of Charge Trap Layer Separation and Floating Gate Formation in the NAND Device - A monolithic three dimensional NAND string includes a vertical semiconductor channel and a plurality of control gate electrodes in different device levels. The string also includes a blocking dielectric layer, a charge storage region and a tunnel dielectric. A first control gate electrode is separated from a second control gate electrode by an air gap located between the major surfaces of the first and second control gate electrodes and/or the charge storage region includes silicide nanoparticles embedded in a charge storage dielectric. | 01-09-2014 |
20140138760 | THREE DIMENSIONAL NAND DEVICE AND METHOD OF CHARGE TRAP LAYER SEPARATION AND FLOATING GATE FORMATION IN THE NAND DEVICE - A monolithic three dimensional NAND string includes a vertical semiconductor channel and a plurality of control gate electrodes in different device levels. The string also includes a blocking dielectric layer, a charge storage region and a tunnel dielectric. A first control gate electrode is separated from a second control gate electrode by an air gap located between the major surfaces of the first and second control gate electrodes and/or the charge storage region includes silicide nanoparticles embedded in a charge storage dielectric. | 05-22-2014 |
20150037950 | COMPACT THREE DIMENSIONAL VERTICAL NAND AND METHOD OF MAKING THEREOF - A NAND device has at least a 3×3 array of vertical NAND strings in which the control gate electrodes are continuous in the array and do not have an air gap or a dielectric filled trench in the array. The NAND device is formed by first forming a lower select gate level having separated lower select gates, then forming plural memory device levels containing a plurality of NAND string portions, and then forming an upper select gate level over the memory device levels having separated upper select gates. | 02-05-2015 |
20150069494 | THREE DIMENSIONAL NAND DEVICE AND METHOD OF CHARGE TRAP LAYER SEPARATION AND FLOATING GATE FORMATION IN THE NAND DEVICE - A monolithic three dimensional NAND string includes a vertical semiconductor channel and a plurality of control gate electrodes in different device levels. The string also includes a blocking dielectric layer, a charge storage region and a tunnel dielectric. A first control gate electrode is separated from a second control gate electrode by an air gap located between the major surfaces of the first and second control gate electrodes and/or the charge storage region includes silicide nanoparticles embedded in a charge storage dielectric. | 03-12-2015 |
20150076584 | HIGH ASPECT RATIO MEMORY HOLE CHANNEL CONTACT FORMATION - A memory device and a method of fabricating a memory device that includes forming a protrusion over a substrate, an etch stop layer over the protrusion, and a stack of alternating material layers over the etch stop layer. The method further includes etching the stack to the etch stop layer to form a memory opening having a first width dimension proximate to the etch stop layer, etching the etch stop layer to provide a void area between the protrusion and a bottom of the memory opening, where the void area has a second width dimension that is larger than the first width dimension, forming a memory film over a sidewall of the memory opening and within the void area over the top surface of the protrusion, etching the memory film to expose the protrusion, and forming a semiconductor channel in the memory opening that is electrically coupled to the protrusion. | 03-19-2015 |
20150079765 | HIGH ASPECT RATIO MEMORY HOLE CHANNEL CONTACT FORMATION - A method of fabricating a semiconductor device, such as a three-dimensional monolithic NAND memory string, includes etching a select gate electrode over a first gate insulating layer over a substrate to form an opening, forming a second gate insulating layer over the sidewalls of the opening, forming a sacrificial spacer layer over the second gate insulating layer on the sidewalls of the opening, and etching the first gate insulating layer over the bottom surface of the opening to expose the substrate, removing the sacrificial spacer layer to expose the second gate insulating layer over the sidewalls of the opening, and forming a protrusion comprising a semiconductor material within the opening and contacting the substrate, wherein the second gate insulating layer is located between the select gate electrode and first and second side surfaces of the protrusion. | 03-19-2015 |