Abstract: A method of forming a memory device includes forming an alternating stack of disposable material layers and silicon nitride layers over a substrate, forming a memory opening through the alternating stack, forming a memory film in the memory opening, forming a vertical semiconductor channel over the memory film in the memory opening, forming a backside trench through the alternating stack, forming laterally-extending cavities by removing the disposable material layers selective to the silicon nitride layers through the backside trench, oxidizing portions of the silicon nitride layers exposed in the laterally-extending cavities to form insulating layers, and replacing remaining portions of the silicon nitride layers with electrically conductive layers.

Abstract: A method of forming a structure includes forming an alternating stack of first material layers and second material layers over a substrate; forming an etch mask material layer containing an opening over the alternating stack; performing a first anisotropic etch process that etches unmasked upper portions of the alternating stack to form a via opening below the opening in the etch mask material layer; forming a combination of a non-conformal cladding liner and a conformal sacrificial spacer layer over the etch mask material layer and in peripheral portions of the via opening; performing a punch-through process that etches a horizontally-extending portion of the conformal sacrificial spacer layer from a bottom portion of the via opening; and vertically extending the via opening by performing a second anisotropic etch process that etches unmasked lower portions of the alternating stack selective to the non-conformal cladding liner and the conformal sacrificial spacer layer.

Abstract: A method includes forming an alternating stack of first material layers and second material layers, forming an etch mask material layer containing an opening over the alternating stack, forming a non-conformal cladding liner over the etch mask material layer, where the non-conformal cladding liner includes a horizontally extending portion that overlies a horizontal top surface of the etch mask material layer and a vertically extending portion contacting a sidewall of the opening in the etch mask material layer, implanting ions of dopant atoms into the non-conformal cladding line, and performing an second anisotropic etch process that etches an unmasked portion of the alternating stack selective to the etch mask material layer and the non-conformal cladding liner. The non-conformal cladding liner provides a higher etch resistance relative to the unmasked portion of the alternating stack after the step of implanting ions than before the step of implanting ions.

Abstract: An alternating stack of insulating layers and electrically conductive layers is formed over a substrate, and a memory opening vertically extends through the alternating stack. The memory opening is laterally expanded at levels of the insulating layers. At least one blocking dielectric layer is formed in the memory opening. A first vertical stack of discrete charge storage elements is formed at levels of the electrically conductive layers. A second vertical stack of discrete dielectric material portions is formed at the levels of the insulating layers. A tunneling dielectric layer is formed over the first vertical stack and the second vertical stack. A vertical semiconductor channel is formed on the tunneling dielectric layer.

Abstract: A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers, memory openings vertically extending through the alternating stack, memory opening fill structures located within a respective one of the memory openings, and a drain-select-level isolation structure. One of the insulating layers is a composite insulating layer including an insulating-material-containing sublayer consisting essentially of an insulating material and an etch stop dielectric material sublayer having a material composition that is different from the insulating material. The etch stop dielectric material sublayer can be employed as an etch stop structure during formation of the drain-select-level isolation structure through drain-select-level electrically conductive layers.

Abstract: A stack including a silicon oxide layer, a germanium-containing layer, and a III-V compound semiconductor layer is formed over a substrate. An alternating stack of insulating layers and spacer material layers is formed over the III-V compound semiconductor layer. The spacer material layers are formed as, or are subsequently replaced with, electrically conductive layers. Memory openings are formed through the alternating stack and into the III-V compound semiconductor layer. Memory opening fill structures including a memory film and a vertical semiconductor channel are formed in the memory openings. The vertical semiconductor channels can include a III-V compound semiconductor channel material that is electrically connected to the III-V compound semiconductor layer. The substrate and at least a portion of the silicon oxide layer can be subsequently detached.

Abstract: A semiconductor structure includes a doped single crystalline semiconductor material layer, a metal or metal alloy source contact layer located over a back side of the doped single crystalline semiconductor material layer, a dielectric isolation layer located over a front side of the doped single crystalline semiconductor material layer, an alternating stack of insulating layers and electrically conductive layers located over the dielectric isolation layer, a memory opening vertically extending through the alternating stack and the dielectric isolation layer and at least partially through the doped single crystalline semiconductor material layer, a memory film and a vertical semiconductor channel located within the memory opening, such that the vertical semiconductor channel vertically extends through the dielectric isolation layer and into the doped single crystalline semiconductor material layer, and a single crystalline semiconductor pedestal contacting the doped single crystalline semiconductor material l

Abstract: A memory device includes an alternating stack of insulating layers and electrically conductive layers, a memory opening vertically extending through the alternating stack, and memory opening fill structures located in the memory opening and including a vertical semiconductor channel, a dielectric material liner laterally surrounding the vertical semiconductor channel, and a vertical stack of discrete memory elements laterally surrounding the dielectric material liner. A subset of the insulating layers a lower insulating sublayer, an upper insulating sublayer overlying the lower insulating sublayer, and a center insulating sublayer located between and in contact with the lower insulating sublayer and the upper insulating sublayer.

Abstract: A memory device includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, a memory opening fill structure including a vertical semiconductor channel and a memory film. The memory film includes a tunneling dielectric layer in contact with the vertical semiconductor channel, a first vertical stack of first dielectric oxide material portions located at levels of the insulating layers and including a dielectric oxide material of a first element, and a second vertical stack of second dielectric oxide material portions located at levels of the electrically conductive layers and including a mixed dielectric oxide material that is a dielectric oxide material of the first element and a second element.

Abstract: A memory device includes a silicon-germanium source contact layer, an alternating stack of insulating layers and electrically conductive layers located over the silicon-germanium source contact layer, and a memory stack structure vertically extending through the alternating stack. The memory stack structure comprises a memory film and a vertical semiconductor channel that contacts the memory film. The silicon-germanium source contact layer contacts a cylindrical portion of an outer sidewall of the vertical semiconductor channel. Logic circuits for operating the memory elements may be provided on a substrate within a same semiconductor die, or may be provided in another semiconductor die that is bonded to the semiconductor die containing the memory device.

Abstract: A semiconductor structure 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 including a vertical semiconductor channel, a memory film in contact with the vertical semiconductor channel, and a vertical stack of tubular dielectric spacers laterally surrounding the memory film. The tubular dielectric spacers may include tubular graded silicon oxynitride portions having a composition gradient such that an atomic concentration of nitrogen decreases with a lateral distance from an outer sidewall of the memory film, or may include tubular composite dielectric spacers including a respective tubular silicon oxide spacer and a respective tubular dielectric metal oxide spacer. Each of the electrically conductive layers has a hammerhead-shaped vertical cross-sectional profile.

Abstract: A method includes forming a first electrode layer over a substrate, forming an ovonic threshold switch (OTS) material layer over the first electrode layer, microwave annealing the OTS material layer, and forming a second electrode layer over the OTS material layer.

Abstract: A semiconductor structure includes an active region including a source region, a drain region, and a channel region extending between the source region and the drain region, a gate stack, and a gate dielectric layer located between the gate stack and the active region. The gate stack includes an electrically conductive gate electrode and a single crystalline III-nitride ferroelectric plate located between the electrically conductive gate electrode and the gate dielectric layer, and an entirety of the single crystalline III-nitride ferroelectric plate is single crystalline.

Abstract: A semiconductor structure includes an active region including a source region, a drain region, and a channel region extending between the source region and the drain region, a gate stack, and a gate dielectric layer located between the gate stack and the active region. The gate stack includes an electrically conductive gate electrode and a single crystalline III-nitride ferroelectric plate located between the electrically conductive gate electrode and the gate dielectric layer, and an entirety of the single crystalline III-nitride ferroelectric plate is single crystalline.

Abstract: A method of depositing a metal includes providing a structure a process chamber, and providing a metal fluoride gas and a growth-suppressant gas into the process chamber to deposit the metal over the structure. The metal may comprise a word line or another conductor of a three-dimensional memory device.

Abstract: A method of depositing a metal includes providing a structure a process chamber, and providing a metal fluoride gas and a growth-suppressant gas into the process chamber to deposit the metal over the structure. The metal may comprise a word line or another conductor of a three-dimensional memory device.

Abstract: A method of depositing a metal includes providing a structure a process chamber, and providing a metal fluoride gas and a growth-suppressant gas into the process chamber to deposit the metal over the structure. The metal may comprise a word line or another conductor of a three-dimensional memory device.

Abstract: A method of forming a structure includes forming an alternating stack of first material layers and second material layers over a substrate, forming a first etch mask material layer, forming a first cladding liner, and forming a via opening through the alternating stack by performing an anisotropic etch process that employs a combination of at least the first cladding liner and the first etch mask material layer as a composite etch mask structure.

Abstract: A method of forming a memory device includes forming an alternating stack of disposable material layers and silicon nitride layers over a substrate, forming a memory opening through the alternating stack, forming a memory film and a vertical semiconductor channel in the memory opening, where the memory film includes a continuous silicon nitride charge storage material layer and a tunneling dielectric layer, forming a backside trench through the alternating stack, forming laterally-extending cavities by removing the disposable material layers selective to the silicon nitride layers through the backside trench, oxidizing portions of the silicon nitride layers and the continuous silicon nitride charge storage material layer exposed in the laterally-extending cavities to form silicon oxide insulating layers and to separate the continuous silicon nitride charge storage material layer into a vertical stack of discrete silicon nitride charge storage material portions, and replacing remaining portions of the silicon

Abstract: An alternating stack of disposable material layers and silicon nitride layers is formed over a substrate. Memory openings are formed through the alternating stack, and memory opening fill structures are formed in the memory openings, wherein each of the memory opening fill structures comprises a charge storage material layer, a tunneling dielectric layer, and a vertical semiconductor channel Laterally-extending cavities are formed by removing the disposable material layers selective to the silicon nitride layers and the memory opening fill structures. Insulating layers comprising silicon oxide are formed by oxidizing surface portions of the silicon nitride layers and portions of the charge storage material layers that are proximal to the laterally-extending cavities. Remaining portions of the charge storage material layers form vertical stacks of discrete charge storage elements. Remaining portions of the silicon nitride layers are replaced with electrically conductive layers.