A method of fabricating a three-dimensional memory includes forming a laminated structure including stacked dummy gate layers and interlayer insulation layers on one side of a substrate. The respective adjacent dummy gate layers and interlayer insulation layers form staircase stairs. At least a part of the interlayer insulation layer of each of the staircase stairs is exposed. The method also includes forming a buffer layer covering the staircase stairs. The method further includes removing a part of the buffer layer covering the sidewalls of the staircase stairs to form spacing grooves. The method further includes forming a dielectric layer that fills the spacing grooves and covers the staircase stairs. The method further includes forming a contact hole penetrating through the dielectric layer and the buffer layer and extending to the dummy gate layer farthest from the substrate.

A memory device includes a memory cell array, and a page buffer circuit connected to the memory cell array through a plurality of bit lines, including a plurality of page buffers arranged in correspondence with the bit lines and each of which includes a sensing node. The plurality of page buffers include a first page buffer, and the first page buffer includes: a first sensing node configured to sense data by corresponding to a first metal wire at a lower metal layer; and a second metal wire electrically connected to the first metal wire and at an upper metal layer located above the lower metal layer, and a boost node corresponding to a third metal wire adjacent to the second metal wire of the upper metal layer and configured to control a boost-up and a boost-down of a voltage of the first sensing node.

A semiconductor memory device includes a conducting layer and an insulating layer that are disposed above a semiconductor substrate, a plurality of pillars that extend in a direction which crosses a surface of the semiconductor substrate, and a plate that is disposed between the plurality of pillars and extends in the same direction as the pillars. A surface of the plate, which faces the pillars, has convex portions and non-convex portions.

A semiconductor memory device includes a conducting layer and an insulating layer that are disposed above a semiconductor substrate, a plurality of pillars that extend in a direction which crosses a surface of the semiconductor substrate, and a plate that is disposed between the plurality of pillars and extends in the same direction as the pillars. A surface of the plate, which faces the pillars, has convex portions and non-convex portions.

An integrated memory assembly comprises a control die bonded to a memory die. The memory die includes multiple non-volatile memory structures (e.g., planes, arrays, groups of blocks, etc.), each comprising a stack of alternating conductive and dielectric layers forming staircases at one or more edges of the non-volatile memory structures. The non-volatile memory structures are positioned with gaps between the non-volatile memory structures such that the gaps separate the staircases of adjacent non-volatile memory structures. Metal interlayer segments positioned in the gaps are connected to a top metal layer positioned above non-volatile memory structures and to one or more electrical circuits on the control die via zero, one or more other metal layers/segments.

A method of manufacturing a semiconductor memory device of one embodiment includes a first resist forming process, a first step forming process, a second resist forming process, and a second step forming process. In the first resist forming process, a first resist layer is formed on the upper surface of the stacked body. In the first step forming process, a lower region of a first stepped portion and an upper region of a second stepped portion are simultaneously formed by etching processing performed via the first opening pattern. In the second resist forming process, a second resist layer having a second opening pattern is formed on the upper surface of the stacked body. In the second step forming process, the upper region of the first stepped portion and the lower region of the second stepped portion are simultaneously formed by etching processing performed via the second opening pattern.

Some embodiments include apparatuses and methods having a substrate, a memory cell string including a body, a select gate located in a level of the apparatus and along a portion of the body, and control gates located in other levels of the apparatus and along other respective portions of the body. At least one of such apparatuses includes a conductive connection coupling the select gate or one of the control gates to a component (e.g., transistor) in the substrate. The connection can include a portion going through a portion of at least one of the control gates.

A control gate electrode and a memory gate electrode of a memory cell of a non-volatile memory are formed in a memory cell region of a semiconductor substrate, and a dummy gate electrode is formed in a peripheral circuit region. Then, n.sup.+-type semiconductor regions for a source or a drain of the memory cell are formed in the memory cell region and n.sup.+-type semiconductor regions for a source or a drain of MISFET are formed in the peripheral circuit region. Then, a metal silicide layer is formed over the n.sup.+-type semiconductor regions but the metal silicide layer is not formed over the control gate electrode, the memory gate electrode, and the gate electrode. Subsequently, the gate electrode is removed and replaced with the gate electrode for MISFET. Then, after removing the gate electrode and replacing it with a gate electrode for MISFET, a metal silicide layer is formed over the memory gate electrode and the control gate electrode.

Memory cells having isolated charge sites and methods of fabricating memory cells having isolated charge sites are described. In an example, a nonvolatile charge trap memory device includes a substrate having a channel region, a source region and a drain region. A gate stack is disposed above the substrate, over the channel region. The gate stack includes a tunnel dielectric layer disposed above the channel region, a first charge-trapping region and a second charge-trapping region. The regions are disposed above the tunnel dielectric layer and separated by a distance. The gate stack also includes an isolating dielectric layer disposed above the tunnel dielectric layer and between the first charge-trapping region and the second charge-trapping region. A gate dielectric layer is disposed above the first charge-trapping region, the second charge-trapping region and the isolating dielectric layer. A gate electrode is disposed above the gate dielectric layer.

A semiconductor device and method of manufacturing the same are provided. In one embodiment, method includes forming a first oxide layer over a substrate, forming a silicon-rich, oxygen-rich, oxynitride layer on the first oxide layer, forming a silicon-rich, nitrogen-rich, and oxygen-lean nitride layer over the oxynitride layer, and forming a second oxide layer on the nitride layer. Generally, the nitride layer includes a majority of charge traps distributed in the oxynitride layer and the nitride layer. Optionally, the method further includes forming a middle oxide layer between the oxynitride layer and the nitride layer. Other embodiments are also described.