According to one embodiment, a method for manufacturing a semiconductor device is disclosed. The method includes forming a co-catalyst layer and catalyst layer above a surface of a semiconductor substrate. The co-catalyst layer and catalyst layer have fcc structure. The fcc structure is formed such that (111) face of the fcc structure is to be oriented parallel to the surface of the semiconductor substrate. The catalyst includes a portion which contacts the co-catalyst layer. The portion has the fcc structure. An exposed surface of the catalyst layer is planarized by oxidation and reduction treatments. A graphene layer is formed on the catalyst layer.

An integrated circuit device includes a capacitor structure, wherein the capacitor structure includes: a bottom electrode over a substrate; a supporter on a sidewall of the bottom electrode; a dielectric layer on the bottom electrode and the supporter; and a top electrode on the dielectric layer and covering the bottom electrode. The bottom electrode comprises: a base electrode layer over the substrate and extending in a first direction that is perpendicular to a top surface of the substrate, and a conductive capping layer including niobium nitride that is between a sidewall of the base electrode layer and the dielectric layer, and also between a top surface of the base electrode layer and the dielectric layer.

Methods for forming a copper seed layer having improved anti-migration properties are described herein. In one embodiment, a method includes forming a first copper layer in a feature, forming a ruthenium layer over the first copper layer in the feature, and forming a second copper layer on the ruthenium layer in the feature. The ruthenium layer substantially locks the copper layer there below in place in the feature, preventing substantial physical migration thereof.

A layout structure including a conductive structure is provided. The layout structure includes a dielectric layer formed on a substrate and a conductive structure formed in the dielectric layer. And the conductive structure further includes a barrier layer, a metal layer formed within the barrier layer, and a high resistive layer sandwiched in between the barrier layer and the metal layer.

Reliability of a plating process and reliability of a component manufactured through the plating process can be improved by suppressing peeling between plating layers formed by electroless plating. In a plating method, a plated component manufactured by the plating method, and a plating system 1 configured to manufacture the plated component by the plating method, a second electroless plating layer 39, which is made of a copper alloy and formed by the electroless plating, is formed on a surface of a first electroless plating layer 38 formed by the electroless plating. The first electroless plating layer 38 is a barrier layer configured to suppress diffusion of copper and is made of cobalt or a cobalt alloy. The second electroless plating layer 39 is a seed layer for forming an electrolytic plating layer of copper on a surface thereof and is made of an alloy of copper and nickel.

A magnetron sputter reactor for sputtering deposition materials such as tantalum, tantalum nitride and copper, for example and its method of use, in which self-ionized plasma (SIP) sputtering and inductively coupled plasma (ICP) sputtering are promoted, either together or alternately, in the same or different chambers. Also, bottom coverage may be thinned or eliminated by ICP resputtering in one chamber and SIP in another. SIP is promoted by a small magnetron having poles of unequal magnetic strength and a high power applied to the target during sputtering. ICP is provided by one or more RF coils which inductively couple RF energy into a plasma. The combined SIP-ICP layers can act as a liner or barrier or seed or nucleation layer for hole. In addition, an RF coil may be sputtered to provide protective material during ICP resputtering. In another chamber an array of auxiliary magnets positioned along sidewalls of a magnetron sputter reactor on a side towards the wafer from the target. The magnetron preferably is a small, strong one having a stronger outer pole of a first magnetic polarity surrounding a weaker outer pole of a second magnetic polarity and rotates about the central axis of the chamber. The auxiliary magnets preferably have the first magnetic polarity to draw the unbalanced magnetic field component toward wafer. The auxiliary magnets may be either permanent magnets or electromagnets.

Semiconductor device and fabrication method are provided. The method includes: providing a base substrate with a bottom metallic layer in the base substrate and a dielectric layer on the base substrate; forming interconnect openings through the dielectric layer and exposing the bottom metallic layer, where each interconnect openings includes a contacting hole and a groove on the contacting hole; forming a first conducting layer in the contacting hole, where the first conducting layer is made of a material having a first conductivity along a direction from the bottom metallic layer to a top surface of the first conducting layer; and after forming the first conducting layer, forming a second conducting layer in the groove, where the second conducting layer is made of a material having a second conductivity along a direction parallel to the top surface of the base substrate and the first conductivity is greater than the second conductivity.

One embodiment is a semiconductor device including: at least one patterned dielectric layer having at least one opening therein, said at least one opening having sidewalls and bottom; at least one barrier layer disposed over the sidewalls and bottom; a first metallic layer disposed over the at least one barrier layer; a second metallic layer disposed over the first metallic layer; and a metallic filling layer disposed over the second metallic layer; wherein: the first metallic layer is continuous over the sidewalls and bottom, has a thickness in a range from about 10 to no more than 40 over a sidewall of the at least one opening; and the second metallic layer, and the metallic filling layer are selected from a group consisting of Cu, Ag, and alloys containing one or more of these metals.

A method of forming a molybdenum-containing material on a substrate is described, in which the substrate is contacted with molybdenum oxytetrachloride (MoOCl.sub.4) vapor under vapor deposition conditions, to deposit the molybdenum-containing material on the substrate. In various implementations, a diborane contact of the substrate may be employed to establish favorable nucleation conditions for the subsequent bulk deposition of molybdenum, e.g., by chemical vapor deposition (CVD) techniques such as pulsed CVD.

The disclosure relates to a method of making molybdenum films utilizing boron and molybdenum nucleation layers. The resulting molybdenum films have low electrical resistivity, are substantially free of boron, and can be made at reduced temperatures compared to conventional chemical vapor deposition processes that do not use the boron or molybdenum nucleation layers. The molybdenum nucleation layer formed by this process can protect the substrate from the etching effect of MoCl.sub.5 or MoOCl.sub.4, facilitates nucleation of subsequent CVD Mo growth on top of the molybdenum nucleation layer, and enables Mo CVD deposition at lower temperatures. The nucleation layer can also be used to control the grain sizes of the subsequent CVD Mo growth, and therefore controls the electrical resistivity of the Mo film.