Abstract: A non-volatile storage apparatus comprises a non-volatile memory structure and a plurality of I/O pads in communication with the non-volatile memory structure. The I/O pads include a power I/O pad, a ground I/O pad and data/control I/O pads. The non-volatile storage apparatus further comprises one or more capacitors connected to the power I/O pad and the ground I/O pad. The one or more capacitors are positioned in one or more metal interconnect layers below the signal lines and/or above device capacitors on the top surface of the substrate.

Abstract: A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, and memory stack structures extending through the alternating stack. Each of the memory stack structures comprises a memory film and a vertical semiconductor channel contacting an inner sidewall of the memory film. The electrically conductive layers include aluminum and silicon and provide low resistance electrically conductive paths as word lines of the three-dimensional memory device. The aluminum-based electrically conductive layers can provide low resistivity, low mechanical stress, and thermal stability for use as high performance word lines.

Abstract: A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, and memory stack structures extending through the alternating stack. Each of the memory stack structures comprises a memory film and a vertical semiconductor channel contacting an inner sidewall of the memory film. The electrically conductive layers include aluminum and silicon and provide low resistance electrically conductive paths as word lines of the three-dimensional memory device. The aluminum-based electrically conductive layers can provide low resistivity, low mechanical stress, and thermal stability for use as high performance word lines.

Abstract: A structure includes a metal interconnect structure embedded in a lower interconnect level dielectric layer overlying a substrate, at least one material layer overlying the metal interconnect structure, a first contact level dielectric layer overlying the at least one material layer; a metal contact via structure vertically extending through the first contact level dielectric layer and the at least one material layer and contacting a top surface of the metal interconnect structure, and an encapsulated tubular cavity laterally surrounding at least a lower portion of the metal contact via structure, and vertically extending through the at least one material layer.

Abstract: Methods for improving channel boosting and reducing program disturb during programming of memory cells within a memory array are described. The memory array may comprise a NAND flash memory structure, such as a vertical NAND structure or a bit cost scalable (BiCS) NAND structure. In some cases, by applying continuous voltage ramping to unselected word lines during or throughout a programming operation, the boosting of channels associated with program inhibited memory cells may be improved. In one example, the slope and timing of a Vpass waveform applied to a group of unselected word lines (e.g., the neighboring word lines of the selected word line) during the programming operation may be set based on the location of the selected word line within the memory array and the locations of the group of unselected word lines within the memory array.

Abstract: An opening is formed through at least one dielectric material layer. A first metallic liner is formed on a bottom surface and sidewalls of the opening by depositing a first metallic material. A metal portion including an elemental metal or an intermetallic alloy of at least two elemental metals is formed on the first metallic liner. A second metallic liner including a second metallic material is formed directly on a top surface of the metal portion. The first metallic material and the second metallic material differ in composition. The first metallic liner and the second metallic liner contact an entirety of all surfaces of the metal portion. The first and second metallic liners can protect the metal portion from a subsequently deposited dielectric material layer, which may be formed as an air-gap dielectric layer after recessing the at least one dielectric material layer.

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.

Abstract: A cylindrical confinement electron gas confined within a two-dimensional cylindrical region can be formed in a vertical semiconductor channel extending through a plurality of electrically conductive layers comprising control gate electrodes. A memory film in a memory opening is interposed between the vertical semiconductor channel and the electrically conductive layers. The vertical semiconductor channel includes a wider band gap semiconductor material and a narrow band gap semiconductor material. The cylindrical confinement electron gas is formed at an interface between the wider band gap semiconductor material and the narrow band gap semiconductor material. As a two-dimensional electron gas, the cylindrical confinement electron gas can provide high charge carrier mobility for the vertical semiconductor channel, which can be advantageously employed to provide higher performance for a three-dimensional memory device.

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 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 three-dimensional resistive memory device includes an alternating stack of electrically conductive layers and insulating layers. Resistive memory elements are provided between the electrically conductive layers and a semiconductor local bit line. The semiconductor local bit line includes a heterostructure of an inner semiconductor material layer having an inner-material band gap and an outer semiconductor material layer having an outer-material band gap that is narrower than the inner-material band. A gate dielectric is located between a gate electrode and the inner semiconductor material layer.

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: 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.

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: Disclosed herein is 3D memory with vertical NAND strings having a III-V compound channel, as well as methods of fabrication. The III-V compound has at least one group III element and at least one group V element. The III-V compound provides for high electron mobility transistor cells. Note that III-V materials may have a much higher electron mobility compared to silicon. Thus, much higher cell current and overall cell performance can be achieved. Also, the memory device may have better read-write efficiency due to much higher carrier mobility and velocity. The tunnel dielectric of the memory cells may have an Al2O3 film in direct contact with the III-V NAND channel. The drain end of the NAND channel may be a metal-III-V alloy in direct contact with a metal region. The body of the source side select transistor could be formed from the III-V compound or from crystalline silicon.

Abstract: A monolithic three-dimensional memory device contains a high mobility metal dichalcogenide channel. A stack of alternating layers comprising first material layers and second material layers is formed over a substrate. A memory opening is formed through the stack of alternating layers. A memory film is formed in the memory opening. A metal dichalcogenide channel is formed on an inner sidewall of the memory film. A dielectric core is formed within the metal dichalcogenide channel. A stack of titanium and gold may be employed to form a drain region to enhance contact. A hafnium oxide, aluminum oxide or hafnium aluminum oxide hafnium aluminum oxide layer may be employed on either side, or on both sides, of the metal dichalcogenide channel to enhance the mobility of electrons in the metal dichalcogenide channel.

Abstract: Systems and methods for performing a partial block erase operation on a portion of a memory array are described. The memory array may include a plurality of vertical NAND strings in which a first set of the plurality of vertical NAND strings are connected to a first drain-side select line, a second set of the plurality of vertical NAND strings are connected to a second drain-side select line, and both the first set and the second set of vertical NAND strings are connected to one or more shared word lines. In cases where a first vertical NAND string of the first set and a second vertical NAND string of the second set are both connected to selected bit lines and the same shared word line, selectivity of memory cells may be provided by applying different voltages to the first drain-side select line and the second drain-side select line.

Abstract: Disclosed herein is 3D memory with vertical NAND strings having a III-V compound channel, as well as methods of fabrication. The III-V compound has at least one group III element and at least one group V element. The III-V compound provides for high electron mobility transistor cells. Note that III-V materials may have a much higher electron mobility compared to silicon. Thus, much higher cell current and overall cell performance can be achieved. Also, the memory device may have better read-write efficiency due to much higher carrier mobility and velocity. The tunnel dielectric of the memory cells may have an Al2O3 film in direct contact with the III-V NAND channel. The drain end of the NAND channel may be a metal-III-V alloy in direct contact with a metal region. The body of the source side select transistor could be formed from the III-V compound or from crystalline silicon.

Abstract: Technology is described for reversible resistivity memory having a crystalline silicon bit line. In one aspect, a memory structure comprises a hollow pillar of crystalline silicon inside of reversible resistivity material. The crystalline silicon may serve as a bit line. The memory structure may further comprise conductive material that forms word lines coupled to the outer surface of the reversible resistivity material. A memory cell comprises a portion of the reversible resistivity material between the crystalline silicon and one of the word lines. In one aspect, the hollow pillar of crystalline silicon surrounds a gate oxide, which surrounds a conductive transistor gate. Thus, the hollow pillar of crystalline silicon may function as a channel of a transistor. In one aspect, the crystalline silicon has predominantly a (100) orientation with respect to an inner surface of the reversible resistivity material. In one aspect, the crystalline silicon is a single crystal.