The present disclosure relates to the field of semiconductor packaging processes, and provides a semiconductor structure and a forming method thereof. The forming method includes: providing a semiconductor substrate, where a surface of the semiconductor substrate is provided with an exposed conductive structure; forming a passivation layer on the surface of the semiconductor substrate and a surface of the exposed conductive structure; etching the passivation layer to form a recess, where a bottom of the recess exposes one end of the conductive structure; forming an adhesion layer on a surface of the recess; and etching to form a hole in the bottom of the recess.

A plating apparatus and plating methods for plating metal layers on a substrate. In an embodiment, a plating method comprises: step 1: immersing a substrate into plating solution of a plating chamber assembly including at least a first anode and a second anode (3001); step 2: turning on a first plating power supply applied on the first anode, setting the first plating power supply to output a power value P.sub.11 and continue with a period T.sub.11 (3002); step 3: when the period T.sub.11 ends, adjusting the first plating power supply applied on the first anode to output a power value P.sub.12 and continue with a period T.sub.12, at the same time, turning on a second plating power supply applied on the second anode, and setting the second plating power supply to output a power value P.sub.21 and continue with a period T.sub.21 (3003); and step 4: when the period T.sub.21 ends, adjusting the second plating power supply applied on the second anode to output a power value P.sub.22 and continue with a period T.sub.22; wherein step 2 to step 4 are performed periodically.

A through via comprising sidewalls having first scallops in a first region and second scallops in a second region and a method of forming the same are disclosed. In an embodiment, a semiconductor device includes a first substrate; and a through via extending through the substrate, the substrate including a first plurality of scallops adjacent the through via in a first region of the substrate and a second plurality of scallops adjacent the through via in a second region of the substrate, each of the scallops of the first plurality of scallops having a first depth, each of the scallops of the second plurality of scallops having a second depth, the first depth being greater than the second depth.

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.

Electronic devices and methods to form electronic devices having a self-aligned via are described. An adhesion enhancement layer is utilized to promote adhesion between the conductive material and the sidewalls of the at least one via opening. The self-aligned vias decrease via resistance and reduce the potential to short to the wrong metal line.

A method for filling recessed features with a low-resistivity metal. The method includes providing a patterned substrate containing a recessed feature formed in a first layer and a second layer that is exposed in the recessed feature, and pre-treating the substrate with a surface modifier that increases metal deposition selectivity on the second layer relative to on the first layer, depositing a metal layer on the substrate by vapor phase deposition, where the metal layer is preferentially deposited on the second layer in the recessed feature, and removing metal nuclei deposited on the first layer, including on a field area and on sidewalls of the first layer in the recessed feature, to selectively form the metal layer on the second layer in the recessed feature. The steps of pre-treating, depositing and removing may be repeated at least once to increase a thickness of the metal layer in the recessed feature.

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 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.

An interconnect structure and an electronic device including the interconnect structure are disclosed. The interconnect structure may include a metal interconnect having a bottom surface and two opposite side surfaces surrounded by a dielectric layer, a graphene layer on the metal interconnect, and a metal bonding layer providing interface adhesion between the metal interconnect and the graphene layer. The metal bonding layer includes a metal material.

Devices and methods that can facilitate hybrid sidewall barrier and low resistance interconnect components are provided. According to an embodiment, a device can comprise a first interconnect material layer that can have a first opening that can comprise a first discontinuous barrier liner coupled to first sidewalls of the first opening and a first continuous barrier layer coupled to the first discontinuous barrier liner and the first sidewalls. The device can further comprise a second interconnect material layer coupled to the first interconnect material layer, the second interconnect material layer can have a second opening that can comprise a second discontinuous barrier liner coupled to second sidewalls of the second opening, a second continuous barrier layer coupled to the second discontinuous barrier liner and the second sidewalls.