A semiconductor device according to the present embodiment comprises a first conductive layer. An interconnection is provided above the first conductive layer. A contact is provided between the first conductive layer and the interconnection. The interconnection includes a first metal layer containing hexagonal titanium (Ti) provided above the first conductive layer, a second metal layer containing tantalum (Ta) having a body-centered cubic lattice-like structure and provided on the first metal layer, and a first wiring material provided on the second metal layer.

The present disclosure provides a semiconductor device with a copper-manganese liner and a method for preparing the semiconductor device. The semiconductor device includes a first well region and a second well region disposed in a semiconductor substrate. The semiconductor device also includes a first dielectric layer disposed over the semiconductor substrate and covering the first well region and the second well region, and a gate structure disposed over the first dielectric layer and between the first well region and the second well region. The semiconductor device further includes a conductive structure disposed over and separated from the first well region by a portion of the first dielectric layer. The conductive feature includes a barrier layer and a conductive plug disposed over the barrier layer, and the barrier layer is made of copper-manganese (CuMn). The first well region, the conductive structure and the portion of the first dielectric layer form an anti-fuse structure.

A redistribution substrate includes a first conductive pattern including a first lower pad and a second lower pad, the first and second lower pads being within a first insulating layer, a second conductive pattern including a first upper pad and a second upper pad, the first and second upper pads being on the first insulating layer, a first via connecting the first lower pad and the first upper pad to each other in the first insulating layer, a second via connecting the second lower pad and the second upper pad to each other in the first insulating layer, and a capacitor between the first lower pad and the first via.

A method of depositing nitride films is disclosed. Some embodiments of the disclosure provide a PEALD process for depositing nitride films which utilizes separate reaction and nitridation plasmas. In some embodiments, the nitride films have improved growth per cycle (GPC) relative to films deposited by thermal processes or plasma processes with only a single plasma exposure. In some embodiments, the nitride films have improved film quality relative to films deposited by thermal processes or plasma processes with only a single plasma exposure.

A method for manufacturing an electronic device includes at least a step (1) of preparing a structure comprising (i) an adhesive film provided with a base material layer, an adhesive resin layer (A) provided on a first surface side of the base material layer, and an adhesive resin layer (B) provided on a second surface side of the base material layer, (ii) an electronic component attached to the adhesive resin layer (A) of the adhesive film, and (iii) a support substrate attached to the adhesive resin layer (B) of the adhesive film; a step (2) of sealing the electronic component with a sealing material; a step (3) of peeling the support substrate from the structure by reducing an adhesive force of the adhesive resin layer (B) by applying an external stimulus; and a step (4) of peeling the adhesive film from the electronic component.

A graphene barrier layer is disclosed. Some embodiments relate to a graphene barrier layer capable of preventing diffusion from a fill layer into a substrate surface and/or vice versa. Some embodiments relate to a graphene barrier layer that prevents diffusion of fluorine from a tungsten layer into the underlying substrate. Additional embodiments relate to electronic devices which contain a graphene barrier layer.

An interconnection structure, along with methods of forming such, are described. The structure includes a dielectric layer, a first conductive feature disposed in the dielectric layer, and a conductive layer disposed over the dielectric layer. The conductive layer includes a first portion and a second portion adj acent the first portion, and the second portion of the conductive layer is disposed over the first conductive feature. The structure further includes a first barrier layer in contact with the first portion of the conductive layer, a second barrier layer in contact with the second portion of the conductive layer, and a support layer in contact with the first and second barrier layers. An air gap is located between the first and second barrier layers, and the dielectric layer and the support layer are exposed to the air gap.

The present disclosure relates to a semiconductor package device including a stacked antenna structure with a high-k laminated dielectric layer separating antenna and ground planes, and a method of manufacturing the structure. A semiconductor die is laterally encapsulated within an insulating structure comprising a first redistributions structure. A second redistribution structure is disposed over and electrically coupled to the first redistribution structure and the die. The second redistribution structure includes the stacked antenna structure which includes first and second conductive planes separated by a high dielectric constant laminated dielectric structure. The first conductive plane includes openings and the second conductive plane is configured to transmit and receive electromagnetic waves through the openings in the first conductive plane.

The present disclosure describes an exemplary method that can prevent or reduce out-diffusion of Cu from interconnect layers to magnetic tunnel junction (MTJ) structures. The method includes forming an interconnect layer over a substrate that includes an interlayer dielectric stack with openings therein; disposing a metal in the openings to form corresponding conductive structures; and selectively depositing a diffusion barrier layer on the metal. In the method, selectively depositing the diffusion barrier layer includes pre-treating the surface of the metal; disposing a precursor to selectively form a partially-decomposed precursor layer on the metal; and exposing the partially-decomposed precursor layer to a plasma to form the diffusion barrier layer. The method further includes forming an MTJ structure on the interconnect layer over the diffusion barrier layer, where the bottom electrode of the MTJ structure is aligned to the diffusion barrier layer.

A semiconductor device includes a semiconductor substrate, a dielectric structure, an electrical insulating and thermal conductive layer, an etch stop layer and a circuit layer. The electrical insulating and thermal conductive layer is disposed over the semiconductor substrate. The etch stop layer includes silicon nitride and is disposed between the semiconductor substrate and the electrical insulating and thermal conductive layer. The dielectric structure is disposed over the electrical insulating and thermal conductive layer, wherein a thermal conductivity of the electrical insulating and thermal conductive layer is substantially greater than a thermal conductivity of the dielectric structure. The circuit layer is disposed in the dielectric structure.