Abstract: A method of forming a three-dimensional memory device, includes forming a lower stack structure of insulating and first sacrificial material layers over a substrate, forming first memory openings through the lower stack structure and filling the first memory openings with a sacrificial fill material, replacing the first sacrificial material layers with first electrically conductive layers, forming an upper stack structure of insulating and second sacrificial material layers over the lower stack structure after replacing the first sacrificial material layers, forming second memory openings through the upper stack structure in areas overlying the first memory openings, replacing the second sacrificial material layers with second electrically conductive layers, removing the sacrificial fill material from the first memory openings underneath the second memory openings to form inter-stack memory openings after replacing the second sacrificial material layers, and forming memory stack structures within the inter-st

Abstract: A memory opening can be formed through a multiple tier structure. Each tier structure includes an alternating stack of sacrificial material layers and insulating layers. After formation of a dielectric oxide layer, the memory opening is filled with a sacrificial memory opening fill structure. The sacrificial material layers are removed selective to the insulating layers and the dielectric oxide layer to form backside recesses. Physically exposed portions of the dielectric oxide layer are removed. A backside blocking dielectric and electrically conductive layers are formed in the backside recesses.

Abstract: A memory opening can be formed through a multiple tier structure. Each tier structure includes an alternating stack of sacrificial material layers and insulating layers. After formation of a dielectric oxide layer, the memory opening is filled with a sacrificial memory opening fill structure. The sacrificial material layers are removed selective to the insulating layers and the dielectric oxide layer to form backside recesses. Physically exposed portions of the dielectric oxide layer are removed. A backside blocking dielectric and electrically conductive layers are formed in the backside recesses. Subsequently, the sacrificial memory opening fill structure is replaced with a memory stack structure including a plurality of charge storage regions and a semiconductor channel. Hydrogen or deuterium from a dielectric core may then be outdiffused into the semiconductor channel.

Abstract: A three dimensional NAND device includes a common vertical channel and electrically isolated control gate electrodes on different lateral sides of the channel in each device level to form different lateral portions of a memory cell in each device level. Dielectric separator structures are located between and electrically isolate the control gate electrodes. The lateral portions of the memory cell in each device level may be electrically isolated by at least one of doping ungated portions of the channel adjacent to the separator structures or storing electrons in the separator structure.

Abstract: Techniques for forming 3D memory arrays are disclosed. Memory openings are filled with a sacrificial material, such as silicon or nitride. Afterwards, a replacement technique is used to remove nitride from an ONON stack and replace it with a conductive material such as tungsten. Afterwards, memory cell films are formed in the memory openings. The conductive material serves as control gates of the memory cells. The control gate will not suffer from corner rounding. ONON shrinkage is avoided, which will prevent control gate shrinkage. Block oxide between the charge storage region and control gate may be deposited after control gate replacement, so the uniformity is good. Block oxide may be deposited after control gate replacement, so TiN adjacent to control gates can be thicker to prevent fluorine attacking the insulator between adjacent control gates. Therefore, control gate to control gate shorting is prevented.

Abstract: High-density semiconductor memory is provided with enhancements to gate-coupling and electrical isolation between discrete devices in non-volatile memory. The intermediate dielectric between control gates and charge storage regions is varied in the row direction, with different dielectric constants for the varied materials to provide adequate inter-gate coupling while protecting from fringing fields and parasitic capacitances. Electrical isolation is further provided, at least in part, by air gaps that are formed in the column (bit line) direction and/or air gaps that are formed in the row (word line) direction.

Abstract: Systems and methods for implementing and using stacked vertical memory array architectures. A first NAND string may be formed or arranged above a second NAND string. The first NAND string may include a first drain-side select gate connected to a first set of memory cell transistors connected to a first source-side select gate. The second NAND string may include a second drain-side select gate connected to a second set of memory cell transistors connected to a second source-side select gate. The first NAND string and the second NAND string may comprise portions of the same or different memory array architectures (e.g., the first NAND string may be part of a memory array that uses U-shaped NAND strings and the second NAND string may be part of a memory array that uses single vertical NAND strings).

Abstract: A method of making a monolithic three dimensional NAND device includes forming a stack of alternating layers of a first material and a second material different from the first material over a substrate, forming a mask layer over the stack and patterning the mask layer to form at least on opening in the mask layer to expose a top layer of the stack. The method also includes forming a metal block in the at least one opening in the mask layer, etching the stack by metal induced localized etch using the metal block in the at least one opening in the mask layer to form at least one opening in the stack and forming at least one layer of the NAND device in the at least one opening.

Abstract: A method of manufacturing a three-dimensional memory device includes forming, a bottom dielectric layer, a bottom sacrificial material layer, and an alternating stack of insulating layers and spacer material layers over a semiconductor substrate, forming a memory opening, forming an epitaxial channel portion and a memory stack structure in the memory opening, forming a backside contact trench, forming a first backside recess by selectively removing the bottom sacrificial material layer, forming a semiconductor oxide layer underneath the bottom dielectric layer and around a material of the epitaxial channel portion, forming second backside recesses by selectively removing the spacer material layers, and forming electrically conductive layers in the first and second backside recesses.

Abstract: A memory device includes a plurality of memory cells arranged in a string substantially perpendicular to the major surface of the substrate in a plurality of device levels, at least one first select gate electrode located between the major surface of the substrate and the plurality of memory cells, at least one second select gate electrode located above the plurality of memory cells, a semiconductor channel having a portion that extends vertically along a direction perpendicular to the major surface, a first memory film contacting a first side of the semiconductor channel, and a second memory film contacting a second side of the semiconductor channel. The second memory film is electrically isolated from the first memory film, and is located at a same level as the first memory film.

Abstract: A method of forming a three-dimensional memory device, includes forming a lower stack structure of insulating and first sacrificial material layers over a substrate, forming first memory openings through the lower stack structure and filling the first memory openings with a sacrificial fill material, replacing the first sacrificial material layers with first electrically conductive layers, forming an upper stack structure of insulating and second sacrificial material layers over the lower stack structure after replacing the first sacrificial material layers, forming second memory openings through the upper stack structure in areas overlying the first memory openings, replacing the second sacrificial material layers with second electrically conductive layers, removing the sacrificial fill material from the first memory openings underneath the second memory openings to form inter-stack memory openings after replacing the second sacrificial material layers, and forming memory stack structures within the inter-st

Abstract: A first stack of alternating layers including first electrically conductive layers and first electrically insulating layers is formed with first stepped surfaces and a first dielectric material portion thereupon. Dielectric pillar structures including a dielectric metal oxide can be formed through the first stepped surfaces. Lower memory openings can be formed, and filled with a disposable material or a lower memory opening structure including a lower semiconductor channel and a doped semiconductor region. At least one dielectric material layer and a second stack of alternating layers including second electrically conductive layers and second electrically insulating layers can be sequentially formed. Upper memory openings can be formed through the second stack and the at least one dielectric material layer. A memory film and a semiconductor channel can be formed after removal of the disposable material, or an upper semiconductor channel can be formed on the doped semiconductor region.

Abstract: Peripheral devices for a three-dimensional memory device can be formed over an array of memory stack structures to increase areal efficiency of a semiconductor chip. First contact via structures and first metal lines are formed over an array of memory stack structures and an alternating stack of insulating layers and electrically conductive layers. A semiconductor material layer including a single crystalline semiconductor material or a polycrystalline semiconductor material is formed over first metal lines. After formation of semiconductor devices on or in the semiconductor material layer, metal interconnect structures including second metal lines and additional conductive via structures are formed to electrically connect nodes of the semiconductor devices to respective first metal lines and to memory devices underneath.

Abstract: A memory stack structure for a three-dimensional device includes an alternating stack of insulator layers and spacer material layers. A memory opening is formed through the alternating stack. A memory material layer, a tunneling dielectric layer, and a silicon oxide liner are formed in the memory opening. A sacrificial liner is subsequently formed over the tunneling dielectric layer. The layer stack is anisotropically etched to physically expose a semiconductor surface of the substrate underneath the memory opening. The sacrificial liner may be removed prior to, or after, the anisotropic etch. The silicon oxide liner is removed after the anisotropic etch. A semiconductor channel layer can be deposited directly on the tunneling dielectric layer as a single material layer without any interface therein.

Abstract: A method of fabricating a semiconductor device, such as a three-dimensional NAND memory string, includes forming a carbon etch stop layer having a first width over a major surface of a substrate, forming a stack of alternating material layers over the etch stop layer, etching the stack to the etch stop layer to form a memory opening having a second width at a bottom of the memory opening that is smaller than the width of the etch stop layer, removing the etch stop layer to provide a void area having a larger width than the second width of the memory opening, forming a memory film over a sidewall of the memory opening and in the void area, and forming a semiconductor channel in the memory opening such that the memory film is located between the semiconductor channel and the sidewall of the memory opening.

Abstract: A monolithic three dimensional NAND string including a stack of alternating first material layers and second material layers different from the first material layers over a major surface of a substrate. The first material layers include a plurality of control gate electrodes and the second material layers include an insulating material and the plurality of control gate electrodes extend in a first direction. The NAND string also includes a semiconductor channel, a blocking dielectric, and a plurality of vertically spaced apart floating gates. Each of the plurality of vertically spaced apart floating gates or each of the second material layers includes a first portion having a first thickness in the second direction, and a second portion adjacent to the first portion in the first direction and having a second thickness in the second direction which is different than the first thickness.

Abstract: A method of making a vertical NAND device includes forming a lower portion of a memory stack over a substrate, forming a lower portion of memory openings in the lower portion of the memory stack, and at least partially filling the lower portion of the memory openings with a sacrificial material. The method also includes forming an upper portion of the memory stack over the lower portion of the memory stack and over the sacrificial material, forming an upper portion of the memory openings in the upper portion of the memory stack to expose the sacrificial material in the lower portion of the memory openings, removing the sacrificial material to connect the lower portion of the memory openings with a respective upper portion of the memory openings to form continuous memory openings, and forming a semiconductor channel in each continuous memory opening.

Abstract: A vertical NAND string device includes a semiconductor channel, where at least one end portion of the semiconductor channel extends substantially perpendicular to a major surface of a substrate, at least one semiconductor or electrically conductive landing pad embedded in the semiconductor channel, a tunnel dielectric located adjacent to the semiconductor channel, a charge storage region located adjacent to the tunnel dielectric, a blocking dielectric located adjacent to the charge storage region and a plurality of control gate electrodes extending substantially parallel to the major surface of the substrate.

Abstract: Techniques for forming 3D memory arrays are disclosed. Memory openings are filled with a sacrificial material, such as silicon or nitride. Afterwards, a replacement technique is used to remove nitride from an ONON stack and replace it with a conductive material such as tungsten. Afterwards, memory cell films are formed in the memory openings. The conductive material serves as control gates of the memory cells. The control gate will not suffer from corner rounding. ONON shrinkage is avoided, which will prevent control gate shrinkage. Block oxide between the charge storage region and control gate may be deposited after control gate replacement, so the uniformity is good. Block oxide may be deposited after control gate replacement, so TiN adjacent to control gates can be thicker to prevent fluorine attacking the insulator between adjacent control gates. Therefore, control gate to control gate shorting is prevented.

Abstract: A multi-tier memory device is formed over a substrate such that memory stack structures extend through an alternating stack of insulating layers and electrically conductive layers within each tier. Bit lines are formed between an underlying tier having drain regions over semiconductor channels and an overlying tier having drain regions under semiconductor channel, such that the bit lines are shared between the underlying tier and the overlying tier. Source lines can be formed over each tier in which source regions overlie semiconductor channels and drain regions. If another tier is present above the source lines, the source lines can be shared between two vertically neighboring tiers.