Abstract: A contact level silicon oxide layer and a silicon nitride layer is formed over a semiconductor device on a semiconductor substrate. A contact via cavity extending to the semiconductor device is formed. A lower contact via structure portion is formed and recessed between top and bottom surface of the silicon nitride layer. An upper contact via structure portion including a hydrogen diffusion barrier material is formed in a remaining volume of the contact via cavity to provide a contact via structure. A three-dimensional memory array is formed over the silicon nitride layer. Metal interconnect structures are formed to provide electrical connection between the contact via structure and a node of the three-dimensional memory array. The hydrogen diffusion barrier material and the silicon nitride layer block downward diffusion of hydrogen.

Abstract: A first-tier structure including a first alternating stack of first insulating layers and first spacer material layers is formed over a substrate. First-tier memory openings and at least one type of first-tier contact openings can be formed simultaneously employing a same anisotropic etch process. The first-tier contact openings formed over stepped surfaces of the first alternating stack may extend through the first alternating stack, or may stop on the stepped surfaces. Sacrificial first-tier opening fill portions are formed in the first-tier openings, and a second-tier structure can be formed over the first-tier structure. Memory openings including volumes of the first-tier memory openings are formed through the multi-tier structure, and memory stack structures are formed in the memory openings. Various contact openings are formed through the multi-tier structure, and various contact via structures are formed in the contact openings.

Abstract: A memory stack structure includes a cavity including a back gate electrode, a back gate dielectric, a semiconductor channel, and at least one charge storage element. In one embodiment, a line trench can be filled with a memory film layer, and a plurality of semiconductor channels can straddle the line trench. The back gate electrode can extend along the lengthwise direction of the line trench. In another embodiment, an isolated memory opening overlying a patterned conductive layer can be filled with a memory film, and the back gate electrode can be formed within a semiconductor channel and on the patterned conductive layer. A dielectric cap portion electrically isolates the back gate electrode from a drain region. The back gate electrode can be employed to bias the semiconductor channel, and to enable sensing of multinary bits corresponding to different amounts of electrical charges stored in a memory cell.

Abstract: A memory device includes an alternating stack of insulating layers and electrically conductive layers. Vertical NAND strings are formed through the alternating stack, each of which includes a drain region, memory cell charge storage transistors, and a pair of drain select transistors in a series connection. A common bit line is electrically connected to drain regions of two vertical NAND strings. The drain select transistors of the two vertical NAND strings are configured such that drain select transistors sharing a first common drain select gate electrode provide a higher threshold voltage for one of the two vertical NAND strings, and drain select transistors sharing a second common drain select gate electrode provide a higher threshold voltage for the other of the two vertical NAND strings. The different threshold voltages can be provided by a combination of a masked ion implantation and selective charge injection.

Abstract: A method of operating a three-dimensional memory device includes applying a target string bias voltage to a selected drain select gate electrode which partially surrounds a row of memory stack structures that directly contact a drain select isolation structure, and applying a neighboring string bias voltage that has a greater magnitude than the target string bias voltage to an unselected drain select gate electrode that contacts the drain select level isolation structure.

Abstract: A contact level silicon oxide layer and a silicon nitride layer is formed over a semiconductor device on a semiconductor substrate. A contact via cavity extending to the semiconductor device is formed. A lower contact via structure portion is formed and recessed between top and bottom surface of the silicon nitride layer. An upper contact via structure portion including a hydrogen diffusion barrier material is formed in a remaining volume of the contact via cavity to provide a contact via structure. A three-dimensional memory array is formed over the silicon nitride layer. Metal interconnect structures are formed to provide electrical connection between the contact via structure and a node of the three-dimensional memory array. The hydrogen diffusion barrier material and the silicon nitride layer block downward diffusion of hydrogen.

Abstract: An array of memory stack structures extends through an alternating stack of insulating layers and electrically conductive layers over a substrate. An array of drain select level assemblies including cylindrical electrode portions is formed over the alternating stack with the same periodicity as the array of memory stack structures. A drain select level isolation strip including dielectric materials can be formed between a neighboring pair of drain select level assemblies employing the drain select level assemblies as a self-aligning template. Alternatively, cylindrical electrode portions can be formed around an upper portion of each memory stack structure. Strip electrode portions are formed on the cylindrical electrode portions after formation of the drain select level isolation strip.

Abstract: A three-dimensional memory device includes an alternating stack of insulating layers and control gate electrodes located over a substrate, a drain select gate device located above the alternating stack, and a vertical semiconductor channel extending through the alternating stack and through the drain select gate device. The drain select gate device contains a floating gate electrode located between the vertical semiconductor channel and a first drain select gate electrode.

Abstract: Contacts to peripheral devices extending through multiple tier structures of a three-dimensional memory device can be formed with minimal additional processing steps. First peripheral via cavities through a first tier structure can be formed concurrently with formation of first memory openings. Sacrificial via fill structures can be formed in the first peripheral via cavities concurrently with formation of sacrificial memory opening fill structures that are formed in the first memory openings. Second peripheral via cavities through a second tier structure can be formed concurrently with formation of word line contact via cavities that extend to top surfaces of electrically conductive layers in the first and second tier structures. After removal of the sacrificial via fill structures, the first and second peripheral via cavities can be filled with a conductive material to form peripheral contact via structures concurrently with formation of word line contact via structures.

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 semiconductor structure includes a memory-level assembly located over a substrate and including at least one alternating stack and memory stack structures vertically extending through the at least one alternating stack. Each of the at least one an alternating stack includes alternating layers of respective insulating layers and respective electrically conductive layers, and each of the electrically conductive layers in the at least one alternating stack includes a respective opening such that a periphery of a respective spacer dielectric portion located in the opening contacts a sidewall of the respective electrically conductive layers. At least one through-memory-level via structure vertically extends through each of the spacer dielectric portions and the insulating layers.

Abstract: A three-dimensional memory structure includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, an array of memory stack structures extending through the alternating stack, an array of drain select level assemblies overlying the alternating stack and having a same periodicity as the array of memory stack structures, drain select gate electrodes laterally surrounding respective rows of the drain select level assemblies, and a drain select level isolation strip located between a neighboring pair of drain select gate electrodes and including a pair of lengthwise sidewalls. Each of the pair of lengthwise sidewalls includes a laterally alternating sequence of planar sidewall portions and convex sidewall portions.

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 trench having a uniform depth is provided in an upper portion of a semiconductor substrate. A continuous dielectric material layer is formed, which includes a gate dielectric that fills an entire volume of the trench. A gate electrode is formed over the gate dielectric such that the gate electrode overlies a center portion of the gate dielectric and does not overlie a first peripheral portion and a second peripheral portion of the gate dielectric that are located on opposing sides of the center portion of the gate dielectric. After formation of a dielectric gate spacer, a source extension region and a drain extension region are formed within the semiconductor substrate by doping respective portions of the semiconductor substrate.

Abstract: A three-dimensional memory structure includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, an array of memory stack structures extending through the alternating stack, an array of drain select level assemblies overlying the alternating stack and having a same periodicity as the array of memory stack structures, drain select gate electrodes laterally surrounding respective rows of the drain select level assemblies, and a drain select level isolation strip located between a neighboring pair of drain select gate electrodes and including a pair of lengthwise sidewalls. Each of the pair of lengthwise sidewalls includes a laterally alternating sequence of planar sidewall portions and convex sidewall portions.

Abstract: An array of memory stack structures extends through an alternating stack of insulating layers and electrically conductive layers over a substrate. An array of drain select level assemblies including cylindrical electrode portions is formed over the alternating stack with the same periodicity as the array of memory stack structures. A drain select level isolation strip including dielectric materials can be formed between a neighboring pair of drain select level assemblies employing the drain select level assemblies as a self-aligning template. Alternatively, cylindrical electrode portions can be formed around an upper portion of each memory stack structure. Strip electrode portions are formed on the cylindrical electrode portions after formation of the drain select level isolation strip.

Abstract: A memory film and a semiconductor channel can be formed within each memory opening that extends through a stack including an alternating plurality of insulator layers and sacrificial material layers. After formation of backside recesses through removal of the sacrificial material layers selective to the insulator layers, a metallic barrier material portion can be formed in each backside recess. A cobalt portion can be formed in each backside recess. Each backside recess can be filled with a cobalt portion alone, or can be filled with a combination of a cobalt portion and a metallic material portion including a material other than cobalt.

Abstract: Discrete silicon nitride portions can be formed at each level of electrically conductive layers in an alternating stack of insulating layers and the electrically conductive layers. The discrete silicon nitride portions can be employed as charge trapping material portions, each of which is laterally contacted by a tunneling dielectric portion on the front side, and by a blocking dielectric portion on the back side. The tunneling dielectric portions may be formed as discrete material portions or portions within a tunneling dielectric layer. The blocking dielectric portions may be formed as discrete material portions or portions within a blocking dielectric layer. The discrete silicon nitride portions can be formed by depositing a charge trapping material layer and selectively removing portions of the charge trapping material layer at levels of the insulating layers. Various schemes may be employed to singulate the charge trapping material layer.

Abstract: A method of fabricating a monolithic three dimensional memory structure is provided. The method includes forming a stack of alternating word line and dielectric layers above a substrate, forming a source line above the substrate, forming a memory hole extending through the alternating word line and dielectric layers and the source line, and forming a mechanical support element on the substrate adjacent to the memory hole.

Abstract: After formation of an alternating stack of insulating layers and sacrificial material layers, a memory opening can be formed through the alternating stack, which is subsequently filled with a columnar semiconductor pedestal portion and a memory stack structure. Breakage of the columnar semiconductor pedestal portion under mechanical stress can be avoided by growing a laterally protruding semiconductor portion by selective deposition of a semiconductor material after removal of the sacrificial material layers to form backside recesses. At least an outer portion of the laterally protruding semiconductor portion can be oxidized to form a tubular semiconductor oxide spacer. Electrically conductive layers can be formed in the backside recesses to provide word lines for a three-dimensional memory device.