A 3-dimensional array of NOR memory strings being organized by planes of NOR memory strings, in which (i) the storage transistors in the NOR memory strings situated in a first group of planes are configured to be programmed, erased, program-inhibited or read in parallel, and (ii) the storage transistors in NOR memory strings situated within a second group of planes are configured for storing resource management data relating to data stored in the storage transistors of the NOR memory strings situated within the first group of planes, wherein the storage transistors in NOR memory strings in the second group of planes are configured into sets.

A method for forming a memory device includes providing an initial semiconductor structure, including a base substrate; a first sacrificial layer formed on the base substrate; a stack structure, disposed on the first sacrificial layer; a plurality of channels, formed through the stack structure and the first sacrificial layer; and a gate-line trench, formed through the stack structure and exposing the first sacrificial layer. The method also includes forming at least one protective layer on the sidewalls of the gate-line trench; removing the first sacrificial layer to expose a portion of each of the plurality of channels and the surfaces of the base substrate, using the at least one protective layer as an etch mask; and forming an epitaxial layer on the exposed surfaces of the base substrate and the plurality of channels.

A semiconductor device includes a channel structure arranged on a substrate and extending in a first direction perpendicular to a top surface of the substrate, the channel structure including a channel layer and a gate insulating layer; a plurality of insulating layers arranged on the substrate and surrounding the channel structure, the plurality of insulating layers spaced apart from each other in the first direction; a plurality of first gate electrodes surrounding the channel structure; and a plurality of second gate electrodes surrounding the channel structure. Between adjacent insulating layers from among the plurality of insulating layers are arranged a first gate electrode from among the plurality of first gate electrodes spaced apart along the first direction from a second gate electrode from among the plurality of second gate electrodes.

A trench is formed by removing a portion of each of the charge accumulation film and the insulating film located between the control gate electrode and the memory gate electrode. The insulating film is formed in the trench so that the upper surface of each of the insulating film and the charge accumulation film is covered with the insulating film. When exposing the upper surface of the control gate electrode and the memory gate electrode, the upper surface of each of the insulating film and the charge accumulation film is not exposed.

Some embodiments include a NAND memory array having a vertical stack of alternating insulative levels and conductive levels. The conductive levels include control gate regions and distal regions proximate the control gate regions. The control gate regions have front surfaces, top surfaces and bottom surfaces. The top and bottoms surfaces extend back from the front surfaces. High-k dielectric material is along the control gate regions. The high-k dielectric material has first regions along the top and bottom surfaces, and has second regions along the front surfaces. The first regions are thicker than the second regions. Charge-blocking material is adjacent to the second regions of the high-k dielectric material. Charge-storage material is adjacent to the charge-blocking material. Gate-dielectric material is adjacent to the charge-storage material. Channel material is adjacent to the gate-dielectric material. Some embodiments include integrated assemblies. Some embodiments include methods of forming integrated assemblies.

Some embodiments include a method of forming a conductive structure. A metal-containing conductive material is formed over a supporting substrate. A surface of the metal-containing conductive material is exposed to at least one radical form of hydrogen and to at least one oxidant. The exposure alters at least a portion of the metal-containing conductive material to thereby form at least a portion of the conductive structure. Some embodiments include a conductive structure which has a metal-containing conductive material with a first region adjacent to a second region. The first region has a greater concentration of one or both of fluorine and boron relative to the second region.

A semiconductor device includes a stacked structure with insulating layers and conductive layers that are alternately stacked on each other, a hard mask pattern on the stacked structure, a channel structure penetrating the hard mask pattern and the stacked structure, insulating patterns interposed between the insulating layers and the channel structure, wherein the insulating patterns protrude farther towards the channel structure than a sidewall of the hard mask pattern, and a memory layer interposed between the stacked structure and the channel structure, wherein the memory layer fills a space between the insulating patterns.

A semiconductor storage device includes first and second stacked bodies, a first semiconductor layer, a first charge storage layer, a conductive layer, and a first silicon oxide layer. The first stacked body includes first insulation layers and first gate electrode layers that are alternately stacked in a first direction. The first semiconductor layer extends in the first stacked body in the first direction. The first charge storage layer is provided between the first semiconductor layer and the first gate electrode layers. The conductive layer is provided between the first stacked body and the second stacked body and extends in the first direction and a second direction. The first silicon oxide layer is provided between the conductive layer and the first gate electrode layers. The first silicon oxide layer containing an impurity being at least one of phosphorus, boron, carbon, and fluorine.

Embodiments of three-dimensional (3D) memory devices having a memory layer that confines electron transportation and methods for forming the same are disclosed. A method for forming a 3D memory device includes the following operations. An initial channel hole is formed in a stack structure having a plurality of first layers and a plurality of second layers alternatingly arranged over a substrate. A portion of each one of the plurality of first layers facing a sidewall of the initial channel hole is removed to form a channel hole. A semiconductor channel structure is formed in the channel hole. The semiconductor channel structure includes a memory layer following a profile of a sidewall of the channel hole. The plurality of first layers are removed to form a plurality of tunnels. Portions of the memory layer are removed, through the tunnels, to divide the memory layer into a plurality of disconnected sub-memory portions.

A semiconductor device including an oxide-nitride-oxide (ONO) structure having a multi-layer charge storing layer and methods of forming the same are provided. Generally, the method involves: (i) forming a first oxide layer of the ONO structure; (ii) forming a multi-layer charge storing layer comprising nitride on a surface of the first oxide layer; and (iii) forming a second oxide layer of the ONO structure on a surface of the multi-layer charge storing layer. Preferably, the charge storing layer comprises at least two silicon oxynitride layers having differing stoichiometric compositions of Oxygen, Nitrogen and/or Silicon. More preferably, the ONO structure is part of a silicon-oxide-nitride-oxide-silicon (SONOS) structure and the semiconductor device is a SONOS memory transistor. Other embodiments are also disclosed.