Abstract: Disclosed herein is a 3D memory with a select transistor, and method for fabricating the same. The select transistor may have a conductive floating gate, a conductive control gate, a first dielectric between the conductive floating gate and the conductive control gate, and a second dielectric between a body and the conductive floating gate. In one aspect, a uniform gate dielectric is formed using lateral epitaxial growth in a recess adjacent a crystalline semiconductor select transistor body, followed by forming the gate dielectric from the epitaxial growth. Techniques help to prevent, or at least reduce, a leakage current between the select transistor control gate and the select transistor body and/or the semiconductor substrate below the select transistor. Therefore, select transistors having a substantially uniform threshold voltage, on current, and S-factor are achieved. Also, select transistors have a high on-current and a steep sub-threshold slope.

Abstract: Techniques are presented for using erase stress and variations in the loop count (number of cycles) for various fail modes in non-volatile memories, including erase disturb and shallow erase. For detection of shallow erase, cells are programmed and then erased, where the variation (delta) in the number of erase loop counts can be used to determine defective blocks. To determine blocks prone to erase disturb, an erase stress is applied to unselected blocks, after which they are programmed: after then erasing one block, the next block can then be read to determine whether it has suffered erase disturb.

Abstract: A three-dimensional memory device includes a plurality of planes, each having a respective alternating stack, strings of memory stack structures which extends through the respective alternating stack, and backside contact via structures vertically extending through the respective alternating stack, extending generally along the first horizontal direction, and laterally separating neighboring pairs of strings of memory stack structures along a second horizontal direction. A first plane includes a first plurality of strings that are laterally spaced apart along the second horizontal direction by a first plurality of backside contact via structures.

Abstract: A first tier structure including a first alternating stack of first insulating layers and first sacrificial material layers is formed over a substrate. First support openings and first memory openings, filled with first support pillar structures and sacrificial pillar structures, respectively, are formed through the first tier structure. A second tier structure including a second alternating stack of second insulating layers and second sacrificial material layers is formed thereabove. Second support openings and second memory openings are formed through the second tier structure such that the second support openings do not overlap with the first support pillar structures and the second memory openings overlie the sacrificial pillar structures. Inter-tier memory openings are formed by removal of the sacrificial pillar structures. Memory stack structures and second support pillar structures are formed in the inter-tier memory openings and the second support openings, respectively.

Abstract: An alternating stack of insulating layers and sacrificial material layers is formed over a substrate. Memory openings are formed through the alternating stack to the substrate. After formation of memory film layers, a sacrificial cover material layer can be employed to protect the tunneling dielectric layer during formation of a bottom opening in the memory film layers. An amorphous semiconductor material layer can be deposited and optionally annealed in an ambient including argon and/or deuterium to form a semiconductor channel layer having a thickness less than 5 nm and surface roughness less than 10% of the thickness. Alternately or additionally, at least one interfacial layer can be employed on either side of the amorphous semiconductor material layer to reduce surface roughness of the semiconductor channel. The ultrathin channel can have enhanced mobility due to quantum confinement effects.

Abstract: A stack of alternating layers comprising first epitaxial semiconductor layers and second epitaxial semiconductor layers is formed over a single crystalline substrate. The first and second epitaxial semiconductor layers are in epitaxial alignment with a crystal structure of the single crystalline substrate. The first epitaxial semiconductor layers include a first single crystalline semiconductor material, and the second epitaxial semiconductor layers include a second single crystalline semiconductor material that is different from the first single crystalline semiconductor material. A backside contact opening is formed through the stack, and backside cavities are formed by removing the first epitaxial semiconductor layers selective to the second epitaxial semiconductor layers. A stack of alternating layers including insulating layers and electrically conductive layers is formed. Each insulating layer contains a dielectric material portion deposited within a respective backside cavity.

Abstract: Techniques for fabricating a memory device which has reduced neighboring word line interference, and a corresponding memory device. The memory device comprises a stack of alternating conductive and dielectric layers, where the conductive layers form word lines or control gates of memory cells. In one aspect, rounding off of the control gate layers due to inadvertent oxidation during fabrication is avoided. An amorphous silicon layer is deposited along the sidewall of the memory holes, adjacent to the control gate layers. Si3N4 is deposited along the amorphous silicon layer and oxidized in the memory hole to form SiO2. The amorphous silicon layer acts as an oxidation barrier for the sacrificial material of the control gate layers. The amorphous silicon layer is subsequently oxidized to also form SiO2. The two SiO2 layers together form a blocking oxide layer.

Abstract: Techniques for fabricating a memory device which has reduced neighboring word line interference, and a corresponding memory device. The memory device comprises a stack of alternating conductive and dielectric layers, where the conductive layers form word lines or control gates of memory cells. In one aspect, rounding off of the control gate layers due to inadvertent oxidation during fabrication is avoided. An amorphous silicon layer is deposited along the sidewall of the memory holes, adjacent to the control gate layers. Si3N4 is deposited along the amorphous silicon layer and oxidized in the memory hole to form SiO2. The amorphous silicon layer acts as an oxidation barrier for the sacrificial material of the control gate layers. The amorphous silicon layer is subsequently oxidized to also form SiO2. The two SiO2 layers together form a blocking oxide layer.

Abstract: A three-dimensional memory device includes a plurality of planes, each having a respective alternating stack, strings of memory stack structures which extends through the respective alternating stack, and backside contact via structures vertically extending through the respective alternating stack, extending generally along the first horizontal direction, and laterally separating neighboring pairs of strings of memory stack structures along a second horizontal direction. A first plane includes a first plurality of strings that are laterally spaced apart along the second horizontal direction by a first plurality of backside contact via structures.

Abstract: Die cracking of a three dimensional memory device may be reduced by adding offsets to backside contact via structures. Each backside contact via structure can include laterally extending portions that extend along a first horizontal direction adjoined by adjoining portions that extend along a horizontal direction other than the first horizontal direction. In order to preserve periodicity of memory stack structures extending through an alternating stack of insulating layers and electrically conductive layers, the distance between an outermost row of a string of memory stack structures between a pair of backside contact via structures and a most proximal backside contact via structure can vary from a laterally extending portion to another laterally extending portion within the most proximal backside contact via structure. Source shunt lines that are parallel to bit lines can be formed over a selected subset of offset portions of the backside contact via structures.

Abstract: An alternating stack of insulating layers and spacer material layers is formed over a semiconductor substrate. Memory openings are formed through the alternating stack. An optional silicon-containing epitaxial pedestal and a memory film are formed in each memory opening. After forming an opening through a bottom portion of the memory film within each memory opening, a germanium-containing semiconductor layer and a dielectric layer is formed in each memory opening. Employing the memory film and the dielectric layer as a crucible, a liquid phase epitaxy anneal is performed to convert the germanium-containing semiconductor layer into a germanium-containing epitaxial channel layer. A dielectric core and a drain region can be formed over the dielectric layer. The germanium-containing epitaxial channel layer is single crystalline, and can provide a higher charge carrier mobility than a polysilicon channel.

Abstract: An alternating stack of insulating layers and sacrificial material layers is formed over a substrate. A dielectric collar structure can be formed prior to formation of an epitaxial channel portion, and can be employed to protect the epitaxial channel portion during replacement of the sacrificial material layers with electrically conductive layers. Exposure of the epitaxial channel portion to an etchant during removal of the sacrificial material layers is avoided through use of the dielectric collar structure. Additionally or alternatively, facets on the top surface of the epitaxial channel portion can be reduced or eliminated by forming the epitaxial channel portion to a height that exceeds a target height, and by recessing a top portion of the epitaxial channel portion. The recess etch can remove protruding portions of the epitaxial channel portion at a greater removal rate than a non-protruding portion.

Abstract: Techniques for fabricating a memory device which has reduced neighboring word line interference, and a corresponding memory device. The memory device comprises a stack of alternating conductive and dielectric layers, where the conductive layers form word lines or control gates of memory cells. In one aspect, the memory device is provided with a reduced dielectric constant (k) in locations of a fringing electric field of the control gate. For example, portions of the dielectric layers can be replaced with a low-k material. One approach involves recessing the dielectric layer and providing a low-k material in the recess. Another approach involves doping a portion of the blocking oxide layer to reduce its dielectric constant. Another approach involves removing a portion of the blocking oxide layer. In another aspect, the memory device is provided with an increased dielectric constant adjacent to the control gates.

Abstract: A non-volatile storage system includes a three dimensional structure comprising vertical columns of memory cells and a managing circuit in communication with the vertical columns. The managing circuit applies one or more patterns of stress voltages to the vertical columns, with different voltages applied to each vertical column of pairs of adjacent vertical columns being tested for shorts. The managing circuit tests for a short in the pairs of adjacent vertical columns after applying the one or more patterns of stress voltages. In one embodiment, the test may comprise programming a memory cell in each vertical column with data that matches the pattern of stress voltages, reading from the memory cells and determining whether data read matches data programmed. The applying of the stress voltages and the testing can be performed as part of a test during manufacturing or in the field during user operation.

Abstract: Techniques for fabricating a memory device which has reduced neighboring word line interference, and a corresponding memory device. The memory device comprises a stack of alternating conductive and dielectric layers, where the conductive layers form word lines or control gates of memory cells. In one aspect, the memory device is provided with a reduced dielectric constant (k) in locations of a fringing electric field of the control gate. For example, portions of the dielectric layers can be replaced with a low-k material. One approach involves recessing the dielectric layer and providing a low-k material in the recess. Another approach involves doping a portion of the blocking oxide layer to reduce its dielectric constant. Another approach involves removing a portion of the blocking oxide layer. In another aspect, the memory device is provided with an increased dielectric constant adjacent to the control gates.

Abstract: A method of making a monolithic three dimensional NAND string comprising forming a stack of alternating layers of a first material and a second material different from the first material over a substrate, forming an at least one front side opening in the stack and forming at least a portion of a memory film in the at least one front side opening. The method also includes forming a semiconductor channel in the at least one front side opening and doping at least one of the memory film and the semiconductor channel with fluorine in-situ during deposition or by annealing in a fluorine containing atmosphere.

Abstract: A memory film layer is formed in a memory opening through an alternating stack of first material layers and second material layers. A sacrificial material layer is deposited on the memory film layer. Horizontal portions of the sacrificial material layer and the memory film layer at the bottom of the memory opening is removed by an anisotropic etch to expose a substrate underlying the memory opening, while vertical portions of the sacrificial material layer protect vertical portions of the memory film layer. After removal of the sacrificial material layer selective to the memory film, a doped semiconductor material layer can be formed directly on the exposed material in the memory opening and on the memory film as a single material layer to form a semiconductor channel of a memory device.

Abstract: Dielectric degradation and electrical shorts due to fluorine radical generation from metallic electrically conductive lines in a three-dimensional memory device can be reduced by forming composite electrically conductive layers and/or using of a metal oxide material for an insulating spacer for backside contact trenches. Each composite electrically conductive layer includes a doped semiconductor material portion in proximity to memory stack structures and a metallic material portion in proximity to a backside contact trench. Fluorine generated from the metallic material layers can escape readily through the backside contact trench. The semiconductor material portions can reduce mechanical stress.

Abstract: Disclosed herein is a 3D memory with vertical NAND strings, and method for fabricating the same. Each vertical NAND string has a source side select transistor having a body in contact with a single crystal silicon substrate. The NAND string channel is formed from silicon germanium (SiGe), which provides for greater electron mobility than silicon. The body of the source side select transistor comprises epitaxial crystalline silicon germanium (SiGe) in contact with the single crystal silicon substrate. By epitaxial crystalline SiGe it is meant that the crystalline SiGe has the same crystalline orientation as the single crystal silicon substrate.

Abstract: Systems and methods for improving performance of a non-volatile memory by utilizing one or more tier select gate transistors between different portions of a NAND string are described. A first memory string tier may comprise a first set of memory cell transistors that may be programmed to store a first set of data and a second memory string tier may comprise a second set of memory cell transistors that are arranged above the first set of transistors and that may be programmed to store a second set of data. Between the first set of memory cell transistors and the second set of memory cell transistors may comprise a tier select gate transistor in series with the first set of memory cell transistors and the second set of memory cell transistors. The tier select gate transistor may comprise a programmable transistor or a non-programmable transistor.