Abstract: Methods of fabricating dual damascene interconnections suitable for use in microelectronic devices and similar applications using a diffusion barrier layer to protect against base materials during processing are provided. The methods include the steps of: filling a via with a hydrogen silsesquioxane (HSQ)-based filler as expressed by the general chemical formula: (RSiO3/2)x(HSiO3/2)y, wherein x and y satisfy the relationships x+y=1 and 0<x<y<1, and R is selected from C4-C24 alkyl, C4-C24 alkenyl, C4-C24 alkoxy, C8-C24 alkenoxy, substituted C4-C24 hydrocarbon, non-substituted C1-C4 hydrocarbon or substituted C1-C4 hydrocarbon; and, partially etching the filler filling the via and an interlayer dielectric to form a trench, which is connected to the via in the region where the dual damascene interconnections are to be formed. Then, the filler remaining in the via is removed, and the trench and the via are filled with an interconnection material to complete the dual damascene interconnections.

Abstract: Provided are a dual damascene interconnection with a metal-insulator-metal (MIM) capacitor and a method of fabricating the same. In this structure, an MIM capacitor is formed on a via-level IMD. After the via-level IMD is formed, while an alignment key used for patterning the MIM capacitor is being formed, a via hole is formed to connect a lower electrode of the MIM capacitor and an interconnection disposed under the via-level IMD. Also, an upper electrode of the MIM capacitor is directly connected to an upper metal interconnection during a dual damascene process.

Abstract: A method of forming a via contact structure using a dual damascene process is disclosed. According to one embodiment a sacrificial layer is formed on an insulating interlayer during the formation of a preliminary via hole. The sacrificial layer has the same composition as a layer filling the preliminary via hole in a subsequent trench formation process. The sacrificial layer and the layer filling the preliminary via hole are simultaneously removed after the trench formation process is carried out. According to another embodiment, a thin capping oxide layer is formed on an insulating interlayer during the formation of a preliminary via hole. The thin capping oxide layer is removed together with a sacrificial layer after a trench formation process is carried out.

Abstract: Methods of forming metal interconnect layers include forming an electrically insulating layer having a contact hole therein, on a semiconductor substrate and then forming a recess in the electrically insulating layer, at a location adjacent the contact hole. The contact hole and the recess are then filled with a first electrically conductive material (e.g., tungsten (W)). At least a portion of the first electrically conductive material within the contact hole is then exposed. This exposure occurs by etching back a portion of the electrically insulating layer using the first electrically conductive material within the contact hole and within the recess as an etching mask. The first electrically conductive material within the recess is then removed to expose another portion of the electrically insulating layer. Following this, the exposed portion of the first electrically conductive material is covered with a second electrically conductive material (e.g.

Abstract: Provided are a dual damascene interconnection with a metal-insulator-metal (MIM) capacitor and a method of fabricating the same. In this structure, an MIM capacitor is formed on a via-level IMD. After the via-level IMD is formed, while an alignment key used for patterning the MIM capacitor is being formed, a via hole is formed to connect a lower electrode of the MIM capacitor and an interconnection disposed under the via-level IMD. Also, an upper electrode of the MIM capacitor is directly connected to an upper metal interconnection during a dual damascene process.

Abstract: A method of forming a via using a dual damascene process can be provided by forming a via in an insulating layer above a lower level copper interconnect and etching into a surface of the lower level copper interconnect in the via using Argon (Ar) sputtering. Then a trench is formed above a lower portion of the via and an upper level copper interconnect is formed in the lower portion of the via and in the trench using a dual damascene process.

Abstract: Methods of forming integrated circuit devices include patterning an electrically insulating layer to support dual-damascene interconnect structures therein. The steps of patterning the electrically insulating layer include using multiple planarization layers having different porosity characteristics. Forming an interconnect structure within an integrated circuit device may include forming an electrically insulating layer on a substrate and forming at least one via hole extending at least partially through the electrically insulating layer. The at least one via hole is filled with a first electrically insulating material having a first porosity. The filled at least one via hole is then covered with a second electrically insulating material layer having a second porosity lower than the first porosity. The second electrically insulating material layer is selectively etched back to expose a first portion of the first electrically insulating material in the at least one via hole.

Abstract: Embodiments of the invention include a MIM capacitor that has a high capacitance that can be manufactured without the problems that affected the prior art. Such a capacitor includes an upper electrode, a lower electrode, and a dielectric layer that is intermediate the upper and the lower electrodes. A first voltage can be applied to the upper electrode and a second voltage, which is different from the first voltage, can be applied to the lower electrode. A wire layer, through which the first voltage is applied to the upper electrode, is located in the same level as or in a lower level than the lower electrode.

Abstract: Provided are an interconnection of a semiconductor device which includes a capping layer and a method for forming the interconnection. The interconnection of the semiconductor device is a copper damascene interconnection where the capping layer is formed as a dual layer of a silicon nitride layer and silicon carbide layer on a copper layer processed by chemical mechanical polishing (CMP). Therefore, it is possible to maintain a high etching selectivity and a low dielectric constant of the silicon carbide layer while providing superior leakage suppression.

Abstract: Embodiments of the invention include a MIM capacitor having a high capacitance with improved manufacturability. Such a capacitor includes an upper electrode, a lower electrode, and a dielectric layer that is intermediate the upper and the lower electrodes. A first voltage can be applied to the upper electrode and a second voltage, which is different from the first voltage, can be applied to the lower electrode. A wire layer, through which the first voltage is applied to the upper electrode, is located in the same level as or in a lower level than the lower electrode.

Abstract: Copper-based metallization is formed in a trench on an integrated circuit substrate by forming a liner of refractory metal in the trench using physical vapor deposition, forming a copper plating seed layer on the liner using physical vapor deposition and then plating copper on the copper plating seed layer. Prior to plating copper on the copper plating seed layer, the liner and/or copper plating seed layer is stuffed with hydrogen, for example by exposing the liner and/or copper plating seed layer to a hydrogen-containing plasma during and/or after formation of the liner and/or copper plating seed layer. Related structures also are disclosed.

Abstract: Provided are an interconnection of a semiconductor device which includes a capping layer and a method for forming the interconnection. The interconnection of the semiconductor device is a copper damascene interconnection where the capping layer is formed as a dual layer of a silicon nitride layer and silicon carbide layer on a copper layer processed by chemical mechanical polishing (CMP). Therefore, it is possible to maintain a high etching selectivity and a low dielectric constant of the silicon carbide layer while providing superior leakage suppression.

Abstract: The present invention discloses a method of fabricating interconnection lines for a semiconductor device. The method includes forming an interlayer insulating layer on a semiconductor substrate. A via hole is formed through the interlayer insulating layer. A via filling material is formed to fill the via hole. A photoresist pattern is formed on the via filling material. The via filling material and the interlayer insulating layer are anisotropically etched using the photoresist pattern as an etch mask to form a trench. A residual portion of the via filling material is removed using two wet etch processes. After removing the residual portion of the via filling material, a conductive layer pattern is formed in the via hole and the trench.

Abstract: A method of fabricating dual damascene interconnections is provided. A dual damascene region is formed in a hybrid dielectric layer having a dielectric constant of 3.3 or less, and a carbon-free inorganic material is used as a via filler. The present invention improves electrical properties of dual damascene interconnections and minimizes defects.

Abstract: Various methods are provided for forming metal interconnection layers of semiconductor devices.

Abstract: A selective copper alloy interconnection in a semiconductor device is provided. The interconnection includes a substrate, a dielectric formed on the substrate, and a first interconnection formed in the dielectric. The first interconnection has a first pure copper pattern. In addition, a second interconnection having a larger width than the first interconnection is formed in the dielectric. The second interconnection has a copper alloy pattern. The copper alloy pattern may be an alloy layer formed of copper (Cu) and an additive material. A method of forming the selective copper alloy pattern is also provided.

Abstract: Provided are an interconnection of a semiconductor device which includes a capping layer and a method for forming the interconnection. The interconnection of the semiconductor device is a copper damascene interconnection where the capping layer is formed as a dual layer of a silicon nitride layer and silicon carbide layer on a copper layer processed by chemical mechanical polishing (CMP). Therefore, it is possible to maintain a high etching selectivity and a low dielectric constant of the silicon carbide layer while providing superior leakage suppression.

Abstract: There is provided a method of forming a dual damascene metal interconnection by employing a sacrificial metal oxide layer. The method includes preparing a semiconductor substrate. An interlayer insulating layer is formed on the semiconductor substrate, and a preliminary via hole is formed by patterning the interlayer insulating layer. A sacrificial via protecting layer is formed on the semiconductor substrate having the preliminary via hole to fill the preliminary via hole, and cover an upper surface of the interlayer insulating layer. A sacrificial metal oxide layer is formed on the sacrificial via protecting layer, the sacrificial metal oxide layer is patterned to form a sacrificial metal oxide pattern having an opening crossing over the preliminary via hole, and exposing the sacrificial via protecting layer.

Abstract: Provided are an interconnection of a semiconductor device which includes a capping layer and a method for forming the interconnection. The interconnection of the semiconductor device is a copper damascene interconnection where the capping layer is formed as a dual layer of a silicon nitride layer and silicon carbide layer on a copper layer processed by chemical mechanical polishing (CMP). Therefore, it is possible to maintain a high etching selectivity and a low dielectric constant of the silicon carbide layer while providing superior leakage suppression.

Abstract: A dual damascene process is disclosed. According to the dual damascene process of the present invention, a first recessed region through an intermetal dielectric layer is filled with a bottom protecting layer, and the bottom protecting layer and the intermetal dielectric layer are simultaneously etched to form a second recessed region that has a shallower depth and wider width than the first recessed region on the first recessed region by using an etch gas selectively etches the intermetal dielectric layer with respect to the bottom protecting layer. In other words, the etch selectivity ratio, the intermetal dielectric layer with respect to the bottom protecting layer, is preferably about 0.5 to about 1.5. Thus, it is possible to form a dual damascene structure without the formation of a byproduct or an oxide fence.