A thin-film transistor comprises an annealed layer comprising crystalline zinc oxide. A passivation layer is adjacent to the thin-film transistor. The passivation layer has a thickness and material composition such that when a dose of radiation from a radiation source irradiates the thin-film transistor, a portion of the dose that includes an approximate maximum concentration of the dose is located within the annealed layer. The annealed layer has a thickness and threshold displacement energies after it has been annealed such that: a) a difference between a transfer characteristic value of the thin-film transistor before and after the dose is less than a first threshold; and b) a difference between a transistor output characteristic value of the thin-film before and after the dose is less than a second threshold. The thresholds are based on a desired performance of the thin-film transistor.

Microfeature workpieces having alloyed conductive structures, and associated methods are disclosed. A method in accordance with one embodiment includes applying a volume of material to a bond pad of a microfeature workpiece, with the volume of material including a first metallic constituent and the bond pad including a second constituent. The method can further include elevating a temperature of the volume of material while the volume of material is applied to the bond pad to alloy the first metallic constituent and the second metallic constituent so that the first metallic constituent is alloyed generally throughout the volume of material. A thickness of the bond pad can be reduced from an initial thickness T1 to a reduced thickness T2.

A method of forming a nanostructure comprises forming self-assembled nucleic acids on at least a portion of a substrate. The method further comprises contacting the self-assembled nucleic acids on the at least a portion of a substrate with a solution comprising at least one repair enzyme to repair defects in the self-assembled nucleic acids. The method may comprise repeating the repair of defects in the self-assembled nucleic acids on the at least a portion of a substrate until a desired, reduced threshold level of defect density is achieved. A semiconductor structure comprises a pattern of self-assembled nucleic acids defining a template having at least one aperture therethrough. At least one of the apertures has a dimension of less than about 50 nm.

Reinforcement structures used with a thinned wafer and methods of manufacture are provided. The method includes forming trenches or vias at least partially through a backside of a thinned wafer attached to a carrier wafer. The method further includes depositing material within the trenches or vias to form reinforcement structures on the backside of the thinned wafer. The method further includes removing excess material from a surface of the thinned wafer, which was deposited during the depositing of the material within the vias.

A method of forming an integrated circuit structure includes forming an etch stop layer over a conductive feature, forming a dielectric layer over the etch stop layer, forming an opening in the dielectric layer to reveal the etch stop layer, and etching the etch stop layer through the opening using an etchant comprising an inhibitor. An inhibitor film comprising the inhibitor is formed on the conductive feature. The method further includes depositing a conductive barrier layer extending into the opening, performing a treatment to remove the inhibitor film after the conductive barrier layer is deposited, and depositing a conductive material to fill a remaining portion of the opening.

An integrated circuit (IC) device includes a lower electrode including a main portion having a sidewall with at least one step portion, and a top portion having a width less than that of the main portion in a lateral direction. An upper support pattern contacts the top portion of the lower electrode. The upper support pattern includes a seam portion. To manufacture an IC device, a mold pattern and an upper sacrificial support pattern through which a plurality of holes pass are formed on a substrate. A plurality of lower electrodes are formed inside the plurality of holes. A peripheral space is formed on the mold pattern. An enlarged peripheral space is formed by reducing a width and a height of the top portion. An upper support pattern is formed to fill the enlarged peripheral space.

Exemplary methods of electroplating may include delivering a current from a power supply through a plating bath of an electroplating chamber for a first period of time. The current delivered may be or include a pulsed current at a duty cycle of less than or about 50%. The methods may include plating a first amount of metal on a substrate within the plating bath. The substrate may define a via within the substrate. The methods may include, subsequent the first period of time, transitioning the power supply to a continuous DC current delivery for a second period of time. The methods may include plating a second amount of metal on the substrate.

Representative implementations of techniques, methods, and formulary provide repairs to processed semiconductor substrates, and associated devices, due to erosion or “dishing” of a surface of the substrates. The substrate surface is etched until a preselected portion of one or more embedded interconnect devices protrudes above the surface of the substrate. The interconnect devices are wet etched with a selective etchant, according to a formulary, for a preselected period of time or until the interconnect devices have a preselected height relative to the surface of the substrate. The formulary includes one or more oxidizing agents, one or more organic acids, and glycerol, where the one or more oxidizing agents and the one or more organic acids are each less than 2% of formulary and the glycerol is less than 10% of the formulary.

A three-dimensional (3D) semiconductor memory device includes a source structure disposed on a horizontal semiconductor layer and including a first source conductive pattern and a second source conductive pattern which are sequentially stacked on the horizontal semiconductor layer, an electrode structure including a plurality of electrodes vertically stacked on the source structure, and a vertical semiconductor pattern penetrating the electrode structure and the source structure, wherein a portion of a sidewall of the vertical semiconductor pattern is in contact with the source structure. The first source conductive pattern includes a discontinuous interface at a level between a top surface of the horizontal semiconductor layer and a bottom surface of the second source conductive pattern.

A method of manufacturing an interconnect structure includes forming an opening through a dielectric layer. The opening exposes a top surface of a first conductive feature. The method further includes forming a barrier layer on sidewalls of the opening, passivating the exposed top surface of the first conductive feature with a treatment process, forming a liner layer over the barrier layer, and filling the opening with a conductive material. The liner layer may include ruthenium.