According to various embodiments, a device may include: a semiconductor region; a metallization layer disposed over the semiconductor region; and a self-organizing barrier layer disposed between the metallization layer and the semiconductor region, wherein the self-organizing barrier layer comprises a first metal configured to be self-segregating from the metallization layer.

A semiconductor structure includes a substrate, bit line structures, and capacitor connection lines. A plurality of bit line structures are arranged on the substrate. Contact holes are formed between adjacent bit line structures. A capacitor connection line includes a first conductive block and a second conductive block. The first conductive block and the second conductive block are sequentially filled in a contact hole. A chamfered structure is formed on a top end of the first conductive block. The chamfered structure is adjacent to a bit line structure. A bottom end of the second conductive block matches the chambered structure.

A semiconductor structure is provided. The semiconductor structure includes a first conductive feature and a second conductive feature disposed in an interlayer dielectric (ILD) layer. The semiconductor structure includes a first graphene layer disposed over the first conductive feature and a second graphene layer disposed over a portion of the second conductive feature. An etch-stop layer (ESL) is horizontally interposed between the first graphene layer and the second graphene layer. A side surface of the first or the second graphene layer directly contacts a side surface of the ESL. A third conductive feature is electrically coupled to the second conductive feature. The third conductive feature is separated from the first graphene layer by a portion of the ESL, and the third conductive feature also directly contacts a top surface of the ESL.

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 is provided for forming a contact plug by bottom-up metal growth. In one step, a substrate is etched to form a contact hole that exposes a silicon-containing feature in the substrate. In one step, a silicide layer is formed on the silicon-containing feature. In one step, a metal seed layer is formed over the silicide layer. In one step, a metal contact layer is deposited over the metal seed layer to form the contact plug in the contact hole.

A method for making a middle-of-line interconnect structure in a semiconductor device includes forming, near a surface of a first interconnect structure comprised of a first metal, a region of varied composition including the first metal and a second element. The method further includes forming a recess within the region of varied composition. The recess laterally extends a first distance along the surface and vertically extends a second distance below the first surface. The method further includes filling the recess with a second metal to form a second interconnect structure that contacts the first interconnect structure.

A semiconductor device and methods of formation are provided. A semiconductor device includes an annealed cobalt plug over a silicide in a first opening of the semiconductor device, wherein the annealed cobalt plug has a repaired lattice structure. The annealed cobalt plug is formed by annealing a cobalt plug at a first temperature for a first duration, while exposing the cobalt plug to a first gas. The repaired lattice structure of the annealed cobalt plug is more regular or homogenized as compared to a cobalt plug that is not so annealed, such that the annealed cobalt plug has a relatively increased conductivity or reduced resistivity.

Embodiments and methods of an interconnect structure are provided. The interconnect structure includes a via, a trench that has an overlapping area with a top of the via, and a first layer of conducting material that has an overlapping area with a bottom of the via. The interconnect also includes a second layer of conducting material formed in the via, and a third layer of conducting material formed in the trench. The second layer of conducting material is in contact with the first layer of conducting material without a barrier in between the two conducting materials. The absence of the barrier at the bottom of the via can reduce the contact resistance of the interconnect structure.

A semiconductor device structure is provided. The semiconductor device structure includes a transistor, a conductive feature on the transistor, a dielectric layer over the conductive feature, and an electrical connection structure in the dielectric layer and on the conductive feature. The electrical connection structure includes a first grain of a first metal material and a first inhibition layer extending along a grain boundary of the first grain of the first metal material, the first inhibition layer is made of a second metal material, and the first metal material and the second metal material have different oxidation/reduction potentials.

A method for forming a semiconductor device structure is provided. The method includes forming a conductive layer over a semiconductor substrate and forming a sacrificial layer over the conductive layer. The method also includes partially removing the sacrificial layer to form a first dummy element. The method further includes etching the conductive layer with the first dummy element as an etching mask to form a conductive line. In addition, the method includes partially removing the first dummy element to form a second dummy element over the conductive line. The method also includes forming a dielectric layer to surround the conductive line and the second dummy element and removing the second dummy element to form a via hole exposing the conductive line. The method further includes forming a conductive via in the via hole.