Abstract: A non-volatile memory cell includes a first electrode, a steering element, a metal oxide storage element located in series with the steering element, a dielectric resistor located in series with the steering element and the metal oxide storage element, and a second electrode.

Abstract: Methods in accordance with this invention form a microelectronic structure by forming a carbon nano-tube (“CNT”) layer, and forming a carbon layer (“carbon liner”) above the CNT layer, wherein the carbon liner comprises: (1) a first portion disposed above and in contact with the CNT layer; and/or (2) a second portion disposed in and/or around one or more carbon nano-tubes in the CNT layer. Numerous other aspects are provided.

Abstract: A semiconductor p-i-n diode and method for forming the same are described herein. In one aspect, a SiGe region is formed between a region doped to have one conductivity (either p+ or n+) and an electrical contact to the p-i-n diode. The SiGe region may serve to lower the contact resistance, which may increase the forward bias current. The doped region extends below the SiGe region such that it is between the SiGe region and an intrinsic region of the diode. The p-i-n diode may be formed from silicon. The doped region below the SiGe region may serve to keep the reverse bias current from increasing as result of the added SiGe region. In one embodiment, the SiGe is formed such that the forward bias current of an up-pointing p-i-n diode in a memory array substantially matches the forward bias current of a down-pointing p-i-n diode which may achieve better switching results when these diodes are used with the R/W material in a 3D memory array.

Abstract: A technique for efficiently handling write operation failures in a memory device which communicates with an external host device allows a page of data to be re-written to a memory array from a page buffer. The host provides user data, a first write address and a write command to the memory device. If the write attempt fails, the host provides a re-write command with a new address, without re-sending the user data to the memory device. Additional data can be received at a data cache of the memory device while a re-write from the page buffer is in progress. The re-written data may be obtained in a copy operation in which the data is read out to the host, modified and written back to the memory device. Additional data can be input to the memory device during the copy operation. Page buffer data can also be modified in place.

Abstract: A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME). 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 layers can be provided in a lateral arrangement, such as an end-to-end, face-to-face, L-shaped or U-shaped arrangement. 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.

Abstract: 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 a resistance-switching layer, a conductive intermediate layer, and first and second electrodes at either end of the RSME. A breakdown layer is electrically between, and in series with, the second electrode and the intermediate layer. The breakdown layer maintains a resistance of at least about 1-10 M? while in a conductive state. 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.

Abstract: A non-volatile storage system includes technology for skipping programming cycles while programming a page (or other unit) of data. While programming a current subset of the page (or other unit) of data, the system will evaluate whether the next subsets of the page (or other unit) of data should be programmed into non-volatile storage elements or skipped. Subsets of the page (or other unit) of data that should not be skipped are programmed into non-volatile storage elements. Some embodiments include transferring the appropriate data to temporary latches/registers, in preparation for programming, concurrently with the evaluation of whether to program or skip the programming.

Abstract: In a first aspect, a method of forming a memory cell is provided, the method including: (1) forming a pillar above a substrate, the pillar comprising a steering element and a metal hardmask layer; (2) selectively removing the metal hardmask layer to create a void; and (3) forming a carbon-based switching material within the void. Numerous other aspects are provided.

Abstract: A method of forming a memory cell is provided, the method including forming a first pillar-shaped element comprising a first semiconductor material, forming a first mold comprising an opening self-aligned with the first pillar-shaped element, and depositing a second semiconductor material in the opening to form a second pillar-shaped element above the first pillar-shaped element. Other aspects are also provided.

Abstract: In some embodiments, a memory cell is provided that includes a storage element formed from an MIM stack including (1) a first conductive layer; (2) an RRS layer formed above the first conductive layer; and (3) a second conductive layer formed above the RRS layer, at least one of the first and second conductive layers comprising a first semiconductor material layer. The memory cell includes a steering element coupled to the storage element, the steering element formed from the first semiconductor material layer of the MIM stack and one or more additional material layers. Numerous other aspects are provided.

Abstract: A method and system for forming reversible resistivity-switching elements is described herein. Forming refers to reducing the resistance of the reversible resistivity-switching element, and may refer to reducing the resistance for the first time. Prior to forming the reversible resistivity-switching element it may be in a high-resistance state. The method may comprise alternating between applying one or more first voltages having a first polarity to the memory cell and applying one or more second voltages having a second polarity that is opposite the first polarity to the memory cell until the reversible resistivity-switching memory element is formed. There may be a rest period between applying the voltages of opposite polarity.

Abstract: A memory array having memory cells comprising a diode and a phase change material is reliably programmed by maintaining all unselected memory cells in a reverse biased state. Thus leakage is low and assurance is high that no unselected memory cells are disturbed. In order to avoid disturbing unselected memory cells during sequential writing, previously selected word and bit lines are brought to their unselected voltages before new bit lines and word lines are selected. A modified current mirror structure controls state switching of the phase change material.

Abstract: Nonvolatile memory cells and methods of forming the same are provided, the methods including forming a first conductor at a first height above a substrate; forming a first pillar-shaped semiconductor element above the first conductor, wherein the first pillar-shaped semiconductor element comprises a first heavily doped layer of a first conductivity type, a second lightly doped layer above and in contact with the first heavily doped layer, and a third heavily doped layer of a second conductivity type above and in contact with the second lightly doped layer, the second conductivity type opposite the first conductivity type; forming a first dielectric antifuse above the third heavily doped layer of the first pillar-shaped semiconductor element; and forming a second conductor above the first dielectric antifuse.

Abstract: Methods and apparatus are provided that include reading a plurality of sets of program pulse tuning instructions from a memory page, the memory page including a plurality of memory cells; and creating a plurality of program pulses in accordance with the plurality of sets of program pulses to program the plurality of memory cells. The plurality of sets of program pulse tuning instructions may be different from one another in at least one respect.

Abstract: The embodiments generally relate to methods of making semiconductor devices, and more particularly, to methods for making semiconductor pillar structures and increasing array feature pattern density using selective or directional gap fill. The technique has application to a variety of materials and can be applied to making monolithic two or three-dimensional memory arrays.

Abstract: In some aspects, a memory cell is provided that includes (1) a steering element above a substrate; and (2) a reversible resistance-switching element coupled to the steering element, wherein the reversible resistance-switching element is selectively formed by: (a) forming a material layer on the substrate; (b) etching the material layer; and (c) oxidizing the etched material layer to form a reversible resistance-switching material. Numerous other aspects are provided.

Abstract: A monolithic three dimensional array of non-volatile storage elements is arranged in blocks. The non-volatile storage elements are connected to bit lines and word lines. The bit lines for each block are grouped into columns of bit lines. The columns of bit lines include top columns of bit lines that are connected to selection circuits on a top side of a respective block and bottom columns of bit lines that are connected to selection circuits on a bottom side of the respective block. Programming of data is pipelined between two or more columns of bit lines in order to increase programming speed.

Abstract: A method of making a semiconductor device includes forming a layer over a substrate, forming a plurality of spaced apart features of imagable material over the layer, forming sidewall spacers on the plurality of features and filling a space between a first sidewall spacer on a first feature and a second sidewall spacer on a second feature with a filler feature. The method also includes removing the sidewall spacers to leave the first feature, the filler feature and the second feature spaced apart from each other, and etching the layer using the first feature, the filler feature and the second feature as a mask.

Abstract: A storage system includes a three-dimensional memory array that has multiple layers of non-volatile storage elements grouped into blocks. The blocks are grouped into bays. The storage system includes array lines of a first type in communication with storage elements, array lines of a second type in communication with storage elements, and sense amplifiers. Each block is geographically associated with two sense amplifiers and all blocks of a particular bay share a group of sense amplifiers associated with the blocks of the particular bay. The system includes multiple sets of local data lines in one or more routing metal layers below the three-dimensional memory array and multiple sets of global data lines in one or more top metal layers above the three-dimensional memory array. Each set of one or more blocks include one set of the local data lines. Each bay includes one set of global data lines that connect to the group of sense amplifiers associated with the blocks of the respective bay.

Abstract: A memory system includes a plurality of non-volatile storage elements that each comprise a diode (or other steering device) in series with reversible resistance-switching material. One or more circuits in the memory system program the non-volatile storage elements by changing the reversible resistance-switching material of one or more non-volatile storage elements to a first resistance state. The memory system can also change the reversible resistance-switching material of one or more of the non-volatile storage elements from the first resistance state to a second resistance state by applying one or more pairs of opposite polarity voltage conditions (e.g., pulses) to the respective diodes (or other steering devices) such that current flows in the diodes (or other steering devices) without operating the diodes (or other steering devices) in breakdown condition.