Abstract: A method is provided for forming conductive layers in semiconductor device channels and vias by using forward current and periodic pulse reverses for filling inward from the sidewalls of the channels and vias. The pulse reversals and inward filling reduce recrystallization rate to improve electromigration resistance and reduce the stress in the conductive layers to eliminate voids.

Abstract: A semiconductor interconnect structure having a substrate with an interconnect structure patterned thereon, a barrier layer, a pre-seed layer, a seed layer, a bulk interconnect layer, and a sealing layer. A process for creating such structures is described. The barrier layer is formed using atomic layer deposition techniques. Subsequently, a pre-seed layer is formed to create a heteroepitaxial interface between the barrier and pre-seed layers. This is accomplished using atomic layer epitaxy techniques to form the pre-seed layer. Thereafter, a seed layer is formed by standard deposition techniques to create a homoepitaxial interface between the seed and pre-seed layers. Upon this layered structure further bulk deposition of conducting materials is done. Excess material is removed from the bulk layer and a sealing layer is formed on top to complete the interconnect structure.

Abstract: A method is provided for forming semiconductor copper seed layers with the copper alloyed with one of the metals from the group comprising tin, magnesium, and aluminum. The alloy further has a graded nitrogen content with the highest concentration of nitrogen proximate a tungsten nitride barrier layer. The high concentration of nitrogen in the copper alloy provides good adhesion of the seed layer to the barrier layer while the lack of nitrogen away from the barrier layer allows the copper conductive to have good adhesion with the pure copper conductive material.

Abstract: An integrated circuit and manufacturing method therefor is provided having a semiconductor substrate with a semiconductor device. A dielectric layer is on the semiconductor substrate and has an opening provided therein. An amorphized barrier layer lines the opening and a seed layer is deposited to line the amorphized barrier layer. A conductor core fills the opening over the barrier layer to form a conductor channel. The seed layer is securely bonded to the amorphized barrier layer and prevents electromigration along the surface between the seed and barrier layers.

Abstract: A semiconductor metalization barrier, and manufacturing method therefor, is provided which is deposited from an aqueous solution containing the Period 4 transition metals of chromium, nickel, and copper deposited on a palladium-activated copper bonding pad.

Abstract: A semiconductor metalization barrier, and manufacturing method therefor, is provided which is a stack of a cobalt layer and cobalt tungsten layer deposited on a copper bonding pad.

Abstract: A method is provided for forming conductive layers in semiconductor channels and vias by using ramped current densities for the electroplating process. The lower density currents are used initially to deposit a fine grain conductive layer in the vias and then higher densities are used to deposit a large grain conductive layer in the channel.

Abstract: A semiconductor metalization barrier, and manufacturing method therefor, is provided which is deposited from an aqueous solution containing the Period 4 transition metals of chromium, nickel, and copper deposited on a palladium-activated copper bonding pad.

Abstract: A semiconductor, and manufacturing method therefor, is provided with a barrier/adhesion layer, having cobalt, nickel, or palladium for semiconductors having conductive materials of copper, silver or gold. The barrier/adhesion layer can be alloyed with between about 0.2% and 4% tantalum, molybdenum, or tungsten to increase barrier effectiveness and lower resistivity.

Abstract: A method is provided for forming conductive layers in semiconductor vias by using forward and reverse pulses during the electroplating process which have time intervals between pulses which increase with time and for forming conductive layers in semiconductor channels by using forward pulses during the electroplating process which have time intervals between pulses which also increase with time. This allows fast deposition while reducing the deposition stress to eliminate voids and speeds up the overall manufacturing process.

Abstract: The present invention relates to the formation of a semiconductor device having selectively fabricated copper interconnect structure that is encapsulated within selectively formed metallic barriers. An exemplary encapsulated copper interconnect structure includes a first low dielectric constant layer (low K1) formed over a substantially completed semiconductor device on which a first sidewall metallic barrier, consisting of metallic material, such as tantalum (Ta), tantalum nitride (TaN) and tungsten nitride WN, is formed to line the wall structure of a via. The metallic liner encapsulates a first, substantially thin (≦0.25 &mgr;m) copper interconnect structure. A second selectively formed thicker (>>0.25 &mgr;m) copper interconnect trench structure is formed overlying and integral with the first copper interconnect structure.

Abstract: A method is provided for forming semiconductor copper seed layers with the copper alloyed with one of the metals from the group comprising tin, magnesium, and aluminum. The alloy further has a graded nitrogen content with the highest concentration of nitrogen proximate a tungsten nitride barrier layer. The high concentration of nitrogen in the copper alloy provides good adhesion of the seed layer to the barrier layer while the lack of nitrogen away from the barrier layer allows the copper conductive to have good adhesion with the pure copper conductive material.

Abstract: A semiconductor, and manufacturing method therefor, is provided with a barrier/adhesion layer, having cobalt, nickel, or palladium for semiconductors having conductive materials of copper, silver or gold. The barrier/adhesion layer can be alloyed with between about 0.2% and 4% tantalum, molybdenum, or tungsten to increase barrier effectiveness and lower resistivity.

Abstract: A semiconductor metalization barrier, and manufacturing method therefor, is provided which is a stack of a cobalt layer and cobalt tungsten layer deposited on a copper bonding pad.