An aspect of the present disclosure relates to a method of forming a barrier layer on a semiconductor device. The method includes placing a substrate into a reaction chamber and depositing a barrier layer over the substrate. The barrier layer includes a metal and a non-metal and the barrier layer exhibits an as-deposited thickness of 4 nm or less. The method further includes densifying the barrier layer by forming plasma from a gas proximate to said barrier layer and reducing the thickness and increasing the density of the barrier layer. In embodiments, during densification 300 Watts or less of power is applied to the plasma at a frequency of 350 kHz to 40 MHz.

The present disclosure provides a method for fabricating a display substrate for a display panel. The method includes providing a flexible organic light-emitting diode (flexible OLED) substrate with a thin-film transistor (TFT) layer on the flexible OLED substrate and a patterned adhesive layer on the TFT layer, wherein the TFT layer includes at least one testing area; providing a barrier film (BF) with a patterned laser barrier layer on a surface of the BF, the surface of the BF facing the TFT layer; and bonding the BF onto the flexible OLED substrate such that at least a portion of the patterned laser barrier corresponds to the at least one testing area. The method also includes irradiating a laser beam along a cutting line on the BF to remove a first portion of the BF.

In a method of fabricating a semiconductor device, an opening is formed inside a dielectric layer above a semiconductor substrate. The opening has a wall. At least one diffusion barrier material is then formed over the wall of the opening by at least two alternating steps, which are selected from the group consisting of a process of physical vapor deposition (PVD) and a process of atomic layer deposition (ALD). A liner layer is formed over the at least one diffusion barrier material.

Interconnect structures and related methods of manufacture improve device reliability and performance by selectively incorporating dopants into conductive lines. Multiple seed layer deposition steps or variable trench bottom areas are used to locally control the dopant concentration within the interconnect structures at the same wiring level, which provides a robust integration approach for metallizing interconnects in future-generation technology nodes.

Interconnect structures and method of forming the same are disclosed herein. An exemplary interconnect structure includes a first contact feature in a first dielectric layer, a second dielectric layer over the first dielectric layer, a third dielectric layer over the second dielectric layer, a second contact feature extending through the second dielectric layer and the third dielectric layer, and a graphene layer between the second contact feature and the third dielectric layer.

A semiconductor device includes a predetermined number of leads, a semiconductor element electrically connected to the leads and supported by one of the leads, and a sealing resin that covers the semiconductor element and a part of each lead. Each lead includes some portions exposed from the sealing resin. A surface plating layer is formed on at least one of the exposed portions of the respective leads.

A method includes forming a trench within a dielectric layer, the trench comprising an interconnect portion and a via portion, the via portion exposing an underlying conductive feature. The method further includes depositing a seed layer within the trench, depositing a carbon layer on the seed layer, performing a carbon dissolution process to cause a graphene layer to form between the seed layer and the underlying conductive feature, and filling a remainder of the trench with a conductive material.

A method for improving reliability of interconnect structures for semiconductor devices is disclosed. The method includes forming a contact structure on a transistor and forming a metallization layer on the contact structure. The forming the metallization layer includes depositing an inter-metal dielectric (IMD) layer on the transistor, forming an opening within the IMD layer to expose a top surface of the contact structure, depositing a metallic layer to fill the opening, forming an electron barrier layer within the IMD layer, and forming a capping layer within the metallic layer. The electron barrier layer has a hole carrier concentration higher than a hole carrier concentration of a portion of the IMD layer underlying the electron barrier layer. The capping layer has a hole carrier concentration higher than a hole carrier concentration of a portion of the metallic layer underlying the capping layer.

A semiconductor device is provided and includes first and second dielectrics, first and second conductive elements, a self-formed-barrier (SFB) and a liner. The first and second dielectrics are disposed with one of first-over-second dielectric layering and second-over-first dielectric layering. The first and second conductive elements are respectively suspended at least partially within a lower one of the first and second dielectrics and at least partially within the other one of the first and second dielectrics. The self-formed-barrier (SFB) is formed about a portion of one of the first and second conductive elements which is suspended in the second dielectric. The liner is deposited about a portion of the other one of the first and second conductive elements which is partially suspended in the first dielectric.

A method for forming an electrical connection structure is provided. The method includes forming a first metal material in an opening of a dielectric layer. The first metal material includes a plurality of grains. The method also includes forming a second metal material over the first metal material. The method also includes annealing the second metal material so that the second metal material diffuses along grain boundaries of the grains of the first metal material. The method also includes removing the second metal material from the upper surface of the first metal material.