Abstract: Memory openings can be formed through an alternating stack of insulating layers and sacrificial material layers. Memory stack structures including charge storage elements can be formed in the memory openings. Inter-level charge leakage in a three-dimensional memory device including a charge trapping layer can be minimized by employing a thin continuous charge trapping material layer within each memory opening. After removal of the sacrificial material layers and formation of backside recesses, discrete charge trapping material portions can be formed by selective growth of a charge trapping material from physically exposed surfaces of each thin continuous charge trapping material layer. The discrete charge trapping material portions can function as primary charge storage regions, and inter-level charge leakage can be minimized by the small thickness of the thin continuous charge trapping material layer.

Abstract: A layer stack including an alternating stack of insulating layers and sacrificial material layers is formed over a substrate. After formation of memory stack structures, backside trenches are formed through the layer stack. The sacrificial material layers are replaced with electrically conductive layers. Drain select level dielectric isolation structures are formed through drain select level of the stack after formation of the electrically conductive layers. The drain select level dielectric isolation structures laterally separate portions of conductive layers that are employed as drain select level gate electrodes for the memory stack structures.

Abstract: A three-dimensional memory device includes an alternating stack of electrically conductive layers and insulating layers located over a substrate, an array of memory stack structures. A source conductive line structure is provided between the substrate and the alternating stack. The source conductive line structure includes a plurality of parallel conductive rail structures extending along a same horizontal direction and adjoined to a common conductive straddling structure. Each memory stack structure straddles a vertical interface between a conductive rail structure and a support matrix. A semiconductor channel in each memory stack structure contacts a respective conductive rail structure and the support matrix.

Abstract: Systems, devices and methods are described including determining a display type and a display mode, preparing stereoscopic image content in response to the display mode, where preparing the stereoscopic image content includes storing a full resolution left image and a full resolution right image in memory, and determining a display refresh rate in response to at least a content frame rate of the stereoscopic image content. The stereoscopic image content may then be processed for display according to the display type, the display refresh rate, and a power policy.

Abstract: A monolithic three dimensional NAND string includes a plurality of control gate electrodes extending substantially parallel to a major surface of a substrate, a memory opening extending substantially perpendicular to the major surface of the substrate and filled with a memory opening material including a memory film, and a dummy opening extending substantially perpendicular to the major surface of the substrate and filled with a dummy channel material which is different from the memory opening material. The dummy channel material has a higher Young's modulus than the memory opening material to offset warpage of the substrate due to the one of compressive and tensile stress imposed by the plurality of control gate electrodes on the substrate.

Abstract: A three-dimensional non-volatile memory is provided with reduced programming variation across word lines. The gate lengths of word lines decrease from the top to the bottom of the memory hole. Increased programming speeds due to a narrow memory hole are offset by a smaller gate length at corresponding positions. A blocking dielectric thickness may also be varied, independently or in combination with a variable word line thickness. The blocking dielectric is formed with a horizontal thickness that is larger at regions adjacent to the lower word line layers and smaller at regions adjacent to the upper word line layers. The larger thickness at the lower word line layers reduces the programming speed in the memory hole for the lower word lines relative to the upper word lines. A variance in programming speed resulting from differences in memory hole diameter may be offset by a corresponding variance in blocking dielectric thickness.

Abstract: Techniques related to image dithering are described herein. The techniques include receiving an image to be displayed at a display device and entering a content adaptive backlight control mode. The image is dithered during the content adaptive backlight control mode. The dithering is disabled during a panel self-refresh mode.

Abstract: Lower level metal interconnect structures are formed over a substrate with semiconductor devices thereupon. A semiconductor material layer and an alternating stack of spacer dielectric layers and insulating layers is formed over the lower level metal interconnect structures. An array of memory stack structures is formed through the alternating stack. Trenches are formed through the alternating stack such that a staircase region is located farther away from a threshold lateral distance from the trenches, while neighboring staircase regions are formed within the threshold lateral distance from the trenches. Portions of the spacer dielectric layers proximal to the trenches are replaced with electrically conductive layers, while a remaining portion of the alternating stack is present in the staircase region.

Abstract: A memory stack structure including a memory film and a vertical semiconductor channel can be formed within each memory opening that extends through a stack including an alternating plurality of insulating layers and sacrificial material layers. After formation of backside recesses through removal of the sacrificial material layers selective to the insulating layers, a backside blocking dielectric layer may be formed in the backside recesses and sidewalls of the memory stack structures. A metallic barrier material portion can be formed in each backside recess. A metallic material portion is formed on the metallic barrier material portion. Subsequently, a metal portion comprising a material selected from cobalt and ruthenium is formed directly on a sidewall of the metallic barrier material portion and a sidewall of the metallic material portion and an overlying insulating surface and an underlying insulating surface.

Abstract: A three-dimensional memory device includes an alternating stack of electrically conductive layers and insulating layers located over a substrate, an array of memory stack structures. An alternating sequence of support pedestal structures and conductive rail structures extending along a same horizontal direction are provided between the substrate and the alternating stack. Each memory stack structure straddles a vertical interface between a conductive rail structure and a support pedestal structure. A semiconductor channel in each memory stack structure contacts a respective conductive rail structure, and is electrically isolated from an adjacent support pedestal structure by a portion of a memory film. The conductive rail structures can function as source regions of memory device.

Abstract: A sacrificial film and an alternating stack of insulating layers and sacrificial material layers are sequentially formed over a substrate. A memory stack structure including a memory film and a vertical semiconductor channel is formed through the alternating stack and the sacrificial film on the substrate. A source level cavity is formed by introducing an etchant or a reactant through a backside trench and removing the sacrificial film. After removal of an annular portion of the memory film, a portion of the vertical semiconductor channel is converted into an annular source region by introducing electrical dopants into the channel. A source contact layer is formed in the source level cavity and directly on the annular source region. The sacrificial material layers are replaced with electrically conductive layers. The annular source region and the source contact layer can provide low source contact resistance in a three-dimensional NAND memory device.

Abstract: Techniques are provided for fabricating a memory device in which the memory cells have a uniform program and erase speed. In one aspect, a memory device is provided with memory holes having diameters which become progressively smaller as a distance between the memory holes and a local interconnect become progressively larger. In another aspect, a fabrication process is provided for such a memory device. The memory holes which are relatively closer to the local interconnect have a relatively thinner blocking oxide layer due to etching used to remove a sacrificial material of the control gate layers. The increased diameter compensates for the thinner blocking oxide layer.

Abstract: A buried source semiconductor layer and p-doped semiconductor material portions are formed over a first portion of a substrate. The buried source semiconductor layer is an n-doped semiconductor material, and the p-doped semiconductor material portions are embedded within the buried source semiconductor layer. An alternating stack of insulating layers and spacer material layers is formed over the substrate. Memory stack structures are formed through the alternating stack. The spacer material layers are formed as, or are replaced with, electrically conductive layers. The buried source semiconductor layer may be formed prior to, or after, formation of the alternating stack. The buried source semiconductor layer underlies the alternating stack and overlies the first portion of the substrate, and contacts at least one surface of the vertical semiconductor channels. The p-doped semiconductor material portions contact at least one surface of a respective subset of the vertical semiconductor channels.

Abstract: Metal floating gate electrodes can be formed for a three-dimensional memory device by forming a memory opening having lateral recesses at levels of spacer material layers between insulating layers, depositing a continuous metal layer, and inducing diffusion and agglomeration of the metal into the lateral recesses to form discrete metal portions employing an anneal process. The metallic material can migrate and form the discrete metal portions due to surface tension, which operates to minimize the surface area of the metallic material. Optionally, two or more continuous metal layers can be employed to form discrete metal portions including at least two metals. Optionally, a selective metal deposition process can be performed to deposit additional metal portions including a different metallic material on the discrete metal portions. The metal floating gate electrodes can be formed without employing an etch process. A tunneling dielectric layer and a semiconductor channel can be subsequently formed.

Abstract: A hybrid phase-in method mitigates the flicker and rolling artifact based on screen change detection or the combination of screen change detection and image spatial analysis. It applies, for example, to solutions that involve backlight and pixel modulation including global dimming and local dimming. If it is full screen change, then no phase-in is needed and the backlight and pixel change can be applied instantly. If it is partial screen change, then content type and spatial image analysis may be used to decide whether to use phase-in or not. The spatial image analysis concept provides additional useful information besides the image brightness analysis for display backlight power saving solutions to make better tradeoffs between power saving and visual quality.

Abstract: A three-dimensional memory device includes an alternating stack of electrically conductive layers and insulating layers located over a substrate, an array of memory stack structures, each memory stack structure extending through the alternating stack and including a memory film and a semiconductor channel laterally surrounded by the memory film, and an array of dielectric pillars located between the alternating stack and the substrate.

Abstract: Disclosed herein are methods of fabricating a source side select (SGS) transistor in 3D memory. The threshold voltage of the SGS transistor accurately meets a target threshold voltage. The SGS transistor has a semiconductor body that resides in a memory hole formed in a stack of alternating layers of two materials. During fabrication, a sacrificial layer may be removed to create recesses between dielectric layers in a stack. The sacrificial layer may be removed by introducing an etchant into slits formed in the stack. Thus, the recess may expose sidewalls of the body of the SGS transistor. An impurity may be introduced into this recess, by way of a slit, in order to dope the source side select transistor. This allows for precise control over the doping profile, which in turn provides for precise control over the threshold voltage of the SGS transistor.

Abstract: Two vertical NAND strings can share a common bit line by providing two pairs of drain select transistors. Channels of each vertical NAND string containing an adjoining pair of drain select transistors are incorporated into a respective vertical semiconductor channel, which is adjoined to a respective drain region which is connected to the common bit line. The drain select transistors have mismatched threshold voltages at each level such that each vertical NAND string includes a level at which a respective drain select transistor has a higher threshold voltage than a counterpart drain select transistor for the other vertical NAND string at the same level. By turning on three drain select transistors out of four, only one vertical NAND string can be activated while the common bit line is biased at a suitable bias voltage. A programming operation or a read operation can be performed only on the activated NAND string.

Abstract: A gate dielectric layer including a tunneling gate dielectric layer, a charge trapping gate dielectric layer, and a cap gate dielectric layer is formed on a horizontal semiconductor channel. An alternating stack of insulating layers and spacer material layers is formed over the gate dielectric layer. The spacer material layers are formed as, or are subsequently replaced with, electrically conducive layers. Memory stack structures are formed through the alternating stack and the gate dielectric layer. Electrical charges can be injected into the charge trapping gate dielectric layer from the horizontal semiconductor channel to program the threshold voltage of a select field effect transistor employing a bottommost electrically conductive layer as a select gate electrode. The programmable threshold voltage can be advantageously employed to provide enhanced electrical isolation among word lines.

Abstract: A NAND memory cell region of a NAND device includes a conductive source line that extends substantially parallel to a major surface of a substrate, a first semiconductor channel that extends substantially perpendicular to a major surface of the substrate, and a second semiconductor channel that extends substantially perpendicular to the major surface of the substrate. At least one of a bottom portion and a side portion of the first semiconductor channel contacts the conductive source line and at least one of a bottom portion and a side portion of the second semiconductor channel contacts the conductive source line.