A memory die includes an alternating stack of insulating layers and electrically conductive layers through which memory opening fill structures vertically extend. The memory die includes at least three memory array regions interlaced with at least two contact regions, or at least three contact regions interlaced with at least two memory array regions in the same memory plane. A logic die including at least two word line driver regions can be bonded to the memory die. The interlacing of the contact regions and the memory array regions can reduce lateral offset of boundaries of the word line driver regions from boundaries of the contact regions.

A variety of applications can include memory devices designed to provide enhanced gate-induced-drain-leakage (GIDL) current during memory erase operations. The enhanced operation can be provided by enhancing the electric field in the channel structures of select gate transistors to strings of memory cells. The channel structures can be implemented as a segmented portion for drains and a portion opposite a gate. The segmented portion includes one or more fins and one or more non-conductive regions with both fins and non-conductive regions extending vertically from the portion opposite the gate. Variations of a border region for the portion opposite the gate with the segmented portion can include fanged regions extending from the fins into the portion opposite the gate or rounded border regions below the non-conductive regions. Such select gate transistors can be formed using a single photo mask process. Additional devices, systems, and methods are discussed.

A memory die includes an alternating stack of insulating layers and electrically conductive layers through which memory opening fill structures vertically extend. The memory die includes at least three memory array regions interlaced with at least two contact regions, or at least three contact regions interlaced with at least two memory array regions in the same memory plane. A logic die including at least two word line driver regions can be bonded to the memory die. The interlacing of the contact regions and the memory array regions can reduce lateral offset of boundaries of the word line driver regions from boundaries of the contact regions.

According to one embodiment, a semiconductor storage device includes a semiconductor pillar including a channel. The channel includes a first channel portion and a second channel portion. A virtual cross section intersecting a first direction and including a first interconnection, a first electrode, the semiconductor pillar, a second electrode, and a second interconnection is determined. Both first end portions of the first channel portion and a first midpoint between both the first end portions are determined in the virtual cross section. Both second end portions of the second channel portion and a second midpoint between both the second end portions are determined in the virtual cross section. In this case, an angle between a second direction and a center line connecting the first midpoint and the second midpoint is an acute angle.

A ferroelectric memory device includes an alternating stack of insulating layers and electrically conductive layers, a memory opening vertically extending through the alternating stack, and a memory opening fill structure located in the memory opening and containing a vertical stack of memory elements and a vertical semiconductor channel. Each memory element within the vertical stack of memory elements includes a crystalline ferroelectric memory material portion and an epitaxial template portion.

A semiconductor memory device according to an embodiment includes a substrate, a source line, word lines, a pillar, an outer peripheral conductive layer, a lower layer conductive layer, and a first contact. The substrate includes a core region and a first region. The outer peripheral conductive layer is provided to surround the core region in the first region. The outer peripheral conductive layer is included in a first layer. The lower layer conductive layer is provided in the first region. The first contact is provided on the lower layer conductive layer to surround the core region in the first region. An upper end of the first contact is included in the first layer. The first contact is electrically connected to the outer peripheral conductive layer.

A semiconductor memory device according to an embodiment includes: a stacked body alternately stacking first insulating layers and gate electrode layers in a first direction; first to third semiconductor layers in the stacked body extending in the first direction; first to third charge accumulation layers; and a second insulating layer in the stacked body extending in the first direction, the second insulating layer contacting the first semiconductor layer or the first charge accumulation layer in a plane perpendicular to the first direction. A first distance between two end surfaces of the gate electrode layer monotonically increases in the first direction in a first cross section parallel to the first direction. A second distance between two end surfaces of the gate electrode layer monotonically increases in the first direction, decreases, and then monotonically increases in a second cross section parallel to the first direction different from the first cross section.

A device area and a marking area neighboring the device area over a dielectric stack are determined. The dielectric stack includes insulating material layers and sacrificial material layers arranged alternatingly over a substrate. The device area and the marking area are patterned using a same etching process to form a marking pattern having a central marking structure in a marking area and a staircase pattern in the device area. The marking pattern and the staircase pattern have a same thickness equal to a thickness of at least one insulating material layer and one sacrificial material layer, and the central marking structure divides the marking area into a first marking sub-area farther from the device area and a second marking sub-area closer to the device area. A first pattern density of the first marking sub-area is greater than or equal to a second pattern density of the second marking sub-area. A photoresist layer is formed to cover the staircase pattern and expose the marking pattern, and the photoresist layer is trimmed to expose a portion of the dielectric stack along a horizontal direction. An etching process is performed to maintain the marking pattern and remove the exposed portion of the dielectric stack and form a staircase.

A semiconductor structure includes a semiconductor substrate, at least one raised dummy feature, at least one memory cell, and at least one word line. The raised dummy feature is present on the semiconductor substrate and defines a cell region on the semiconductor substrate. The memory cell is present on the cell region. The word line is present adjacent to the memory cell.

A semiconductor memory device comprises: a plurality of first conductive layers arranged separated from each other in a first direction; a plurality of second conductive layers arranged, electrically insulated from the plurality of first conductive layers, at a different position in a second direction intersecting the first direction with respect to the first conductive layers; a plurality of memory structures; and a source structure. Respective one ends of the plurality of memory structures and one end of the source structure are electrically connected. The respective other ends of the plurality of memory structures are respectively electrically connected to different first wirings of a plurality of first wirings formed in the same layer in the first direction. The other end of the source structure is electrically connected to a second wiring formed in a different layer from the plurality of first wirings in the first direction.