Embodiments of source structure of a three-dimensional (3D) memory device and method for forming the source structure of the 3D memory device are disclosed. In an example, a NAND memory device includes a substrate, an alternating conductor/dielectric stack, a NAND string, a source conductor layer, and a source contact. The alternating conductor/dielectric stack includes a plurality of conductor/dielectric pairs above the substrate. The NAND string extends vertically through the alternating conductor/dielectric stack. The source conductor layer is above the alternating conductor/dielectric stack and is in contact with an end of the NAND string. The source contact includes an end in contact with the source conductor layer. The NAND string is electrically connected to the source contact by the source conductor layer. In some embodiments, the source conductor layer includes one or more conduction regions each including one or more of a metal, a metal alloy, and a metal silicide.

A semiconductor device includes a lower structure including a substrate, a first interconnection layer extending in a first direction on the lower structure, and including a first metal, a first via contacting a portion of an upper surface of the first interconnection layer and including a second metal, a second via contacting at least a portion of an upper surface of the first via and having a maximum width narrower than a maximum width of the first via, and a second interconnection layer connected to the second via and extending in a second direction. The first interconnection layer has inclined side surfaces in which a width of the first interconnection layer becomes narrower towards an upper region of the first interconnection layer, and the first via has inclined side surfaces in which a width of the first via becomes narrower towards an upper region of the first via.

In some embodiments, the present disclosure relates to method of forming an integrated circuit, including forming a semiconductor device on a frontside of a semiconductor substrate; depositing a dielectric layer over a backside of the semiconductor substrate; patterning the dielectric layer to form a first opening in the dielectric layer so that the first opening exposes a surface of the backside of the semiconductor substrate; depositing a glue layer having a first thickness over the first opening; filling the first opening with a first material to form a backside contact that is separated from the semiconductor substrate by the glue layer; and depositing more dielectric layers, bonding contacts, and bonding wire layers over the dielectric layer to form a second bonding structure on the backside of the semiconductor substrate, so that the backside contact is coupled to the bonding contacts and the bonding wire layers.

A design method of a dummy pattern layout including the following steps is provided. An integrated circuit layout design including resistor elements is obtained via a computer. The locations of dummy conductive structures are configured, wherein the dummy conductive structures are aligned with the resistor elements. The locations of dummy support patterns are configured, wherein each of the dummy support patterns is configured between two adjacent dummy conductive structures, and each of the dummy conductive structures is equidistant from the dummy support patterns on both sides.

Methods, systems, and devices for memory arrays having graded memory stack resistances are described. An apparatus may include a first subset of memory stacks having a first resistance based on a physical and/or electrical distance of the first subset of memory stacks from at least one of a first driver component or a second driver component. The apparatus may include a second subset of memory stacks having a second resistance that is less than the first resistance based on a physical and/or electrical distance of the second subset of memory from at least one of the first driver component or the second driver component.

A semiconductor device includes a first source/drain region and a second source/drain region disposed on opposite sides of a plurality of conductive layers. A dielectric layer overlies the first source/drain region, the second source/drain region, and the plurality of conductive layers. An electrical contact extends through the dielectric layer and the first source/drain region, where a first surface of the electrical contact is a surface of the electrical contact that is closest to the substrate, a first surface of the plurality of conductive layers is a surface of the plurality of conductive layers that is closest to the substrate, and the first surface of the electrical contact is closer to the substrate than the first surface of the plurality of conductive layers.

A die assembly comprising: a first component layer having conductive through-connections in an insulator, a second component layer comprising a die, and an active device layer (ADL) at an interface between the first component layer and the second component layer. The ADL comprises active elements electrically coupled to the first component layer and the second component layer. The die assembly further comprises a bonding layer electrically coupling the ADL to the second component layer. In some embodiments, the die assembly further comprises another ADL at another interface between the first component layer and a package support opposite to the interface. The first component layer may comprise another die having through-substrate vias (TSVs). The die and the another die may be fabricated using different process nodes.

A semiconductor structure may include a metal line, a via above and in electrical contact with the metal lines, and a dielectric layer positioned along a top surface of the metal lines. A top surface of the dielectric layer may be below the dome shaped tip of the via. A top portion of the via may include a dome shaped tip. The semiconductor structure may include a liner positioned along the top surface of the dielectric layer and a top surface of the dome shaped tip of the via. The liner may be made of tantalum nitride or titanium nitride. The dielectric layer may be made of a low-k material. The metal line and the via may be made of ruthenium. The metal line may be made of molybdenum.

A method may include providing a device structure in the semiconductor device. The device structure may include a buried device contact, a first dielectric layer, disposed over the buried device contact; and a device element, where the device element includes a TiN layer. The method may include implanting an ion species into the TiN layer, wherein the ion species comprises a seed material for selective tungsten deposition.

A film deposition method includes preparing a substrate having an insulating film formed thereon, forming a seed layer on the insulating film, and supplying a molybdenum-containing gas and a reducing gas to the substrate having the seed layer famed thereon, to foam a molybdenum film on the seed layer.