Abstract: A 3D NAND storage device includes a plurality of layers containing doped semiconductor material interleaved with a plurality of layers of dielectric material. Each of the pillars forming the 3D NAND storage device includes a plurality of memory cells and a drain-end select gate (SGD). The pillars are separated by a hollow channel in which a plurality of film layers, including at least a lower film layer and an upper film layer have been deposited. The systems and methods described herein remove at least the upper film layer proximate the SGD while maintaining the film layers proximate the memory cells. Such an arrangement beneficially permits tailoring the film layers proximate the SGD prior to depositing the channel film layer in the hollow channel. The systems and methods described herein permit the deposition of a continuous channel film layer proximate both the memory cells and the SGD.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes a staircase structure disposed over a substrate. The staircase structure includes a plurality of layer stacks, where each layer stack is made of a first material layer over a portion of a second material layer. The staircase structure further includes a plurality of landing pads. where each landing pad is disposed over another portion of the second material layer of a respective layer stack.

Abstract: Embodiments of semiconductor structures for wafer flatness control and methods for using and forming the same are disclosed. In an example, a model indicative of a flatness difference of a wafer between a first direction and a second direction is obtained. The flatness difference is associated with one of a plurality of fabrication stages of a plurality of semiconductor devices on a front side of the wafer. A compensation pattern is determined for reducing the flatness difference based on the model. At the one of the plurality of the fabrication stages, a compensation structure is formed on a backside opposite to the front side of the wafer based on the compensation pattern to reduce the flatness difference.

Abstract: Computer memory technology is disclosed. In one example, a method for isolating computer memory blocks in a memory array from one another can include forming an opening between adjacent blocks of memory structures. The method can also include forming a protective liner layer on at least the memory structures. The method can further include disposing isolating material in the opening and on the protective liner layer. The method can even further include removing the isolating material on the protective liner layer. The method can additionally include removing the protective liner layer on the memory structures. Associated devices and systems are also disclosed.

Abstract: Embodiments of interconnect structures of a three-dimensional (3D) memory device and method for forming the interconnect structures are disclosed. In an example, a 3D NAND memory device includes a semiconductor substrate, an alternating layer stack disposed on the semiconductor substrate, and a dielectric structure, which extends vertically through the alternating layer stack, on an isolation region of the substrate. Further, the alternating layer stack abuts a sidewall surface of the dielectric structure and the dielectric structure is formed of a dielectric material. The 3D memory device additionally includes one or more through array contacts that extend vertically through the dielectric structure and the isolation region, and one or more channel structures that extend vertically through the alternating layer stack.

Abstract: A memory cell includes a select device and a capacitor electrically coupled in series with the select device. The capacitor includes two conductive capacitor electrodes having ferroelectric material there-between. The capacitor has an intrinsic current leakage path from one of the capacitor electrodes to the other through the ferroelectric material. There is a parallel current leakage path from the one capacitor electrode to the other. The parallel current leakage path is circuit-parallel the intrinsic path and of lower total resistance than the intrinsic path. Other aspects are disclosed.

Abstract: Various embodiments disclose a 3D memory device, including a substrate; a plurality of conductor layers disposed on the substrate; a plurality of NAND strings disposed on the substrate; and a plurality of slit structures disposed on the substrate. The plurality of NAND strings can be arranged perpendicular to the substrate and in a hexagonal lattice orientation including a plurality of hexagons, and each hexagon including three pairs of sides with a first pair perpendicular to a first direction and parallel to a second direction. The second direction is perpendicular to the first direction. The plurality of slit structures can extend in the first direction.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes a staircase structure disposed over a substrate. The staircase structure includes a plurality of layer stacks, where each layer stack is made of a first material layer over a portion of a second material layer. The staircase structure further includes a plurality of landing pads, where each landing pad is disposed over another portion of the second material layer of a respective layer stack.

Abstract: A method for forming a 3D memory device is disclosed. The method comprises: forming an alternating conductive/dielectric stack on a substrate; forming a slit vertically penetrating the alternating conductive/dielectric stack; forming an isolation layer on a sidewall of the slit; forming a first conductive layer covering the isolation layer; performing a plasma treatment followed by a first doping process to the first conductive layer; forming a second conductive layer covering the first conductive and filling the slit; performing a second doping process followed by a rapid thermal crystallization process to the second conductive layer; removing an upper portion of the first conductive layer and the second conductive layer to form a recess in the slit; and forming a third conductive layer in the recess.

Abstract: Embodiments of interconnect structures of a three-dimensional (3D) memory device and method for forming the interconnect structures are disclosed. In an example, a 3D NAND memory device includes a semiconductor substrate, an alternating layer stack disposed on the semiconductor substrate, and a dielectric structure, which extends vertically through the alternating layer stack, on an isolation region of the substrate. Further, the alternating layer stack abuts a sidewall surface of the dielectric structure and the dielectric structure is formed of a dielectric material. The 3D memory device additionally includes one or more through array contacts that extend vertically through the dielectric structure and the isolation region, and one or more channel structures that extend vertically through the alternating layer stack.

Abstract: Methods and structures of a three-dimensional memory device are disclosed. In an example, the memory device includes a first alternating conductor/dielectric stack disposed on the substrate and a layer of silicon carbide disposed over the first alternating conductor/dielectric stack. A second alternating conductor/dielectric stack is disposed on the silicon carbide layer. The memory device includes one or more first structures extending orthogonally with respect to the surface of the substrate through the first alternating conductor/dielectric stack and over the epitaxially-grown material disposed in the plurality of recesses, and one or more second structures extending orthogonally with respect to the surface of the substrate through the second alternating conductor/dielectric stack. The one or more second structures are substantially aligned over corresponding ones of the one or more first structures.

Abstract: Various embodiments disclose a 3D memory device, including a substrate; a plurality of conductor layers disposed on the substrate; a plurality of NAND strings disposed on the substrate; and a plurality of slit structures disposed on the substrate. The plurality of NAND strings can be arranged perpendicular to the substrate and in a hexagonal lattice orientation including a plurality of hexagons, and each hexagon including three pairs of sides with a first pair perpendicular to a first direction and parallel to a second direction. The second direction is perpendicular to the first direction. The plurality of slit structures can extend in the first direction.

Abstract: The present invention provides a method for diagnosing and determining prognosis of certain cancers (e.g., esophageal squamous cell carcinoma or ESCC) in a subject by detecting suppressed expression of the DLEC1 gene, which in some cases is due to elevated methylation level in the genomic sequence of this gene. A kit and device useful for such a method are also provided. In addition, the present invention provides a method for treating cancer by increasing DLEC1 gene expression or activity.

Abstract: Aspects of the disclosure provide a semiconductor device. The semiconductor device includes gate layers and insulating layers that are stacked alternatingly along a first direction perpendicular to a substrate of the semiconductor device in a first region upon the substrate. The gate layers and the insulating layers are stacked of a stair-step form in a second region. The semiconductor device includes a channel structure that is disposed in the first region. The channel structure and the gate layers form a stack of transistors in a series configuration with the gate layers being gates for the transistors. The semiconductor device includes a contact structure disposed in the second region, and a first dummy channel structure disposed in the second region and around the contact structure. The first dummy channel structure is patterned with a first shape that is different from a second shape of the channel structure.

Abstract: A semiconductor device includes a string of transistors stacked along a vertical direction above a substrate of the semiconductor device. The string can include a first substring, a channel connector disposed above the first substring, and a second substring. The first substring includes a first channel structure having a first channel layer and a first gate dielectric structure that extend along the vertical direction. The second substring is stacked above the channel connector, and has a second channel structure that includes a second channel layer and a second gate dielectric structure that extend along the vertical direction. The channel connector, electrically coupling the first and the second channel layer, is disposed below the second gate dielectric structure to enable formation of a conductive path in a bottom region of the second channel layer. The bottom region is associated with a lowermost transistor in the second substring.

Abstract: Embodiments of methods for forming three-dimensional (3D) memory devices are disclosed. In an example, a peripheral device is formed on a first substrate. A first interconnect layer is formed above the peripheral device on the first substrate. A dielectric stack including a plurality of dielectric/sacrificial layer pairs and a plurality of memory strings each extending vertically through the dielectric stack is formed on a second substrate. A second interconnect layer is formed above the memory strings on the second substrate. The first substrate and the second substrate are bonded, so that the first interconnect layer is below and in contact with the second interconnect layer. The second substrate is thinned after the bonding. A memory stack is formed below the thinned second substrate and including a plurality of conductor/dielectric layer pairs by replacing, with a plurality of conductor layers, sacrificial layers in the dielectric/sacrificial layer pairs.

Abstract: Embodiments of semiconductor structures for wafer flatness control and methods for using and forming the same are disclosed. In an example, a model indicative of a flatness difference of a wafer between a first direction and a second direction is obtained. The flatness difference is associated with one of a plurality of fabrication stages of a plurality of semiconductor devices on a front side of the wafer. A compensation pattern is determined for reducing the flatness difference based on the model. At the one of the plurality of the fabrication stages, a compensation structure is formed on a backside opposite to the front side of the wafer based on the compensation pattern to reduce the flatness difference.

Abstract: Methods and structures of a three-dimensional memory device are disclosed. In an example, the memory device includes a substrate and a multiple-stack staircase structure. The multiple-stack staircase structure can include a plurality of staircase structures stacked over the substrate. Each one of the plurality of staircase structures can include a plurality of conductor layers each between two insulating layers. The memory device can also include a filling structure over the multiple-stack staircase structure, a semiconductor channel extending through the multiple-stack staircase structure, and a supporting pillar extending through the multiple-stack staircase structure and the filling structure. The semiconductor channel can include unaligned sidewall surfaces, and the supporting pillar can include aligned sidewall surfaces.

Abstract: Embodiments of methods for forming three-dimensional (3D) memory devices are disclosed. In an example, a peripheral device is formed on a first substrate. A first interconnect layer is formed above the peripheral device on the first substrate. A dielectric stack including a plurality of dielectric/sacrificial layer pairs and a plurality of memory strings each extending vertically through the dielectric stack is formed on a second substrate. A second interconnect layer is formed above the memory strings on the second substrate. The first substrate and the second substrate are bonded, so that the first interconnect layer is below and in contact with the second interconnect layer. The second substrate is thinned after the bonding. A memory stack is formed below the thinned second substrate and including a plurality of conductor/dielectric layer pairs by replacing, with a plurality of conductor layers, sacrificial layers in the dielectric/sacrificial layer pairs.