Undesired deposition of metals on a lipseal (lipseal plate-out) during electrodeposition of metals on semiconductor substrates is minimized or eliminated by minimizing or eliminating ionic current directed at a lipseal. For example, electrodeposition can be conducted such as to avoid contact of a lipseal with a cathodically biased conductive material on the semiconductor substrate during the course of electroplating. This can be accomplished by shielding a small selected zone proximate the lipseal to suppress electrode-position of metal proximate the lipseal, and to avoid contact of metal with a lipseal. In some embodiments shielding is accomplished by sequentially using lipseals of different inner diameters during electroplating of metals into through-resist features, where a lipseal having a smaller diameter is used during a first electroplating step and serves as a shield blocking electrodeposition in a selected zone. In a second electroplating step, a lipseal of a larger inner diameter is used.

Disclosed are an interconnect structure, an electronic device including the same, and a method of manufacturing the interconnect structure. The interconnect structure includes a dielectric layer; a conductive interconnect on the dielectric layer; and a graphene cap layer on the conductive interconnect. The graphene cap layer contains graphene quantum dots, has a carbon content of 80 at % or more, and has an oxygen content of 15 at % or less.

Embodiments include forming a die, the die including a pad and a passivation layer over the pad. A via is formed to the pad through the passivation layer. A solder cap is formed on the via, where a first material of the solder cap flows to the sidewall of the via. In some embodiments, the via is encapsulated in a first encapsulant, where the first encapsulant is a polymer or molding compound selected to have a low co-efficient of thermal expansion and/or low curing temperature. In some embodiments, the first material of the solder cap is removed from the sidewall of the via by an etching process and the via is encapsulated in a first encapsulant.

Embodiments include forming a die, the die including a pad and a passivation layer over the pad. A via is formed to the pad through the passivation layer. A solder cap is formed on the via, where a first material of the solder cap flows to the sidewall of the via. In some embodiments, the via is encapsulated in a first encapsulant, where the first encapsulant is a polymer or molding compound selected to have a low co-efficient of thermal expansion and/or low curing temperature. In some embodiments, the first material of the solder cap is removed from the sidewall of the via by an etching process and the via is encapsulated in a first encapsulant.

A method for manufacturing a transistor being a bottom-gate transistor is provided. The method for manufacturing a transistor includes a step of forming a first metal layer 32 on an insulator layer 20 provided on a substrate 10 including a gate electrode, a step of applying a resist onto the first metal layer 32, and patterning the first metal layer 32 by a photolithographic method, an oxide film removal step of removing an oxide film 26 formed on the patterned first metal layer 32, and a step of forming a source electrode and a drain electrode by forming a second metal layer 42 on the first metal layer 32.

A display device includes a first substrate, a light-emitting element, a light conversion layer, and a color filter layer. The light-emitting element is disposed on the first substrate. The light conversion layer is disposed on the light-emitting element. In addition, the color filter layer is overlapped the light-emitting element and the light conversion layer.

A semiconductor device that comprises a substrate with a primary surface and a secondary surface opposite to the primary surface. The primary surface provides a semiconductor active device. The semiconductor device includes a base metal layer deposited on the secondary surface and within the substrate via in which a vacancy is formed, and an additional metal layer on the base metal layer, the additional metal layer having different wettability against a solder as compared to the base metal layer whereby the solder is contactable by the base metal layer and repelled by the additional metal layer. The semiconductor device is die-bonded on the assembly substrate by interposing the solder between the secondary surface and the assembly substrate. The base metal layer in a portion that excepts the substrate via and a periphery of the substrate via by partly removing the additional metal layer is in contact with the solder.

A semiconductor device that comprises a substrate with a primary surface and a secondary surface opposite to the primary surface. The primary surface provides a semiconductor active device. The semiconductor device includes a base metal layer deposited on the secondary surface and within the substrate via in which a vacancy is formed, and an additional metal layer on the base metal layer, the additional metal layer having different wettability against a solder as compared to the base metal layer whereby the solder is contactable by the base metal layer and repelled by the additional metal layer. The semiconductor device is die-bonded on the assembly substrate by interposing the solder between the secondary surface and the assembly substrate. The base metal layer in a portion that excepts the substrate via and a periphery of the substrate via by partly removing the additional metal layer is in contact with the solder.

A semiconductor device includes a gate structure on a semiconductor fin, a dielectric layer on the gate structure, and a gate contact extending through the dielectric layer to the gate structure. The gate contact includes a first conductive material on the gate structure, a top surface of the first conductive material extending between sidewalls of the dielectric layer, and a second conductive material on the top surface of the first conductive material.

A technique of improving an adhesion between a metal precipitated in a recess of a substrate and a surface partitioning the recess in an electroless plating processing in which a plated metal is deposited from the bottom of the recess is provided. A substrate liquid processing method includes preparing a substrate including a recess and a wiring exposed at a bottom of the recess; forming a self-assembled monolayer on a side wall of the recess; attaching an intermolecular binder, which is allowed to be bonded to both a metal and the self-assembled monolayer, to the self-assembled monolayer; and burying, by supplying an electroless plating solution to the recess in a state where the intermolecular binder is attached to the self-assembled monolayer to precipitate the metal in the recess, the metal in the recess while bringing the metal into close contact with the intermolecular binder.