Abstract: A transistor comprising a deposited dual-layer spacer structure and method of fabrication. A polysilicon layer is deposited over a gate dielectric, and is subsequently etched to form the polysilicon gate electrode of the transistor. Next, oxide is deposited over the surface of the gate electrode, followed by deposition of a second dielectric layer. Spacers are then formed adjacent to the gate electrode by etching back the second dielectric layer using a substantially anisotropic etch which etches the second dielectric layer faster than it etches the oxide.

Abstract: A method of integrating a polymeric interlayer dielectric. The method comprises forming a dielectric layer comprising a polymer on a conductive layer formed on a substrate. A sacrificial hard mask is then formed on the dielectric layer. A first photoresist layer is then patterned on the sacrificial hard mask to define a first etched region, which is formed through the dielectric layer while substantially all of the first photoresist layer is removed. A sacrificial fill layer then covers the sacrificial hard mask and fills the first etched region. A second photoresist layer is patterned over the sacrificial fill layer to define a second etched region which is formed through the sacrificial fill layer and the dielectric layer while substantially all of the second photoresist layer and the sacrificial fill layer are simultaneously removed.

Abstract: A method of forming an interconnection including the steps of depositing a first masking material over a first conductive region of an integrated circuit substrate and depositing a dielectric material over the first masking material. The method also includes forming a via through the dielectric material to expose the first masking material and a second masking material is deposited in a portion of the via. A trench is formed in the dielectric material over a portion of the via and the second masking material is removed from the via. The via is then extended through the first masking material and a conductive material is deposited in the via.

Abstract: Multiple level interconnect structures and methods for fabricating the interconnect structures are disclosed. The interconnect structures may contain an interconnect line, an electrolessly deposited metal layer formed over the interconnect line, a via formed over the metal layer, and a second interconnect line formed over the via. Often the metal layer contains a cobalt or nickel alloy and provides an etch stop layer for formation of an opening corresponding to the via. The metal layer may provide protection to the underlying interconnect line and may replace a traditional protective dielectric layer. The metal layer is conductive, rather than dielectric, and provides a shunt for passage of electrical current between the via and the interconnect line. Similar metal layers may also be used within the interconnect structures as via liner layers and via plugs.

Abstract: Multiple level interconnect structures and methods for fabricating the interconnect structures are disclosed. The interconnect structures may contain an interconnect line, an electrolessly deposited metal layer formed over the interconnect line, a via formed over the metal layer, and a second interconnect line formed over the via. Often the metal layer contains a cobalt or nickel alloy and provides an etch stop layer for formation of an opening corresponding to the via. The metal layer may provide protection to the underlying interconnect line and may replace a traditional protective dielectric layer. The metal layer is conductive, rather than dielectric, and provides a shunt for passage of electrical current between the via and the interconnect line. Similar metal layers may also be used within the interconnect structures as via liner layers and via plugs.

Abstract: A method of forming an air gap intermetal layer dielectric (ILD) to reduce capacitive coupling between electrical conductors in proximity. The method entails forming first and second electrical conductors over a substrate, wherein the electrical conductors are laterally spaced apart by a gap. Then, forming a gap bridging dielectric layer that extends over the first electrical conductor, the gap, and the second electrical conductor. In order to form a bridge from one electrical conductor to the other electrical conductor, the gap bridging dielectric materials should have poor gap filling characteristics. This can be attained by selecting and/or modifying a dielectric material to have a sufficiently high molecular weight and/or surface tension characteristic such that the material does not substantially sink into the gap. An example of such a material is a spin-on-polymer with a surfactant and/or other additives.

Abstract: A method of forming an interconnection including the steps of forming a sacrificial material that comprises a physical property that is generally insensitive to a photo-reaction in a via through a dielectric material to a masking material over a conductive material. The method also includes forming a trench over in the dielectric material over the via and removing the sacrificial material from the via.

Abstract: A single step electroplating process for interconnect via fill and metal line formation on a semiconductor substrate is disclosed. In this process, a barrier layer is formed onto a surface of a substrate that has at least one via and then a conductive layer is formed onto the barrier layer. Next, a photoresist layer is applied and patterned on top of the conductive layer. The via plugs and metal lines are then deposited on the substrate simultaneously using an electroplating process. After the electroplating process is completed, the photoresist and the conductive layer between the deposited metal lines are removed. The process provides a simple, economical and highly controllable means of forming metal interconnect systems while avoiding the difficulties associated with depositing and patterning metal by traditional semiconductor fabrication techniques.

Abstract: An improved method of forming an integrated circuit, which includes forming a conductive layer on a substrate, then forming a dielectric layer on the conductive layer. After forming the dielectric layer, a layer of photoresist is patterned to define a region to be etched. A first etched region is then formed by removing a first portion of the dielectric layer. That first etched region is filled with a preferably light absorbing sacrificial material having dry etch properties similar to those of the dielectric layer. A second etched region is then formed by removing the sacrificial material and a second portion of the dielectric layer. This improved method may be used to make an integrated circuit that includes a dual damascene interconnect.

Abstract: An improved method of forming an integrated circuit, which includes forming a conductive layer on a substrate, then forming a dielectric layer on the conductive layer. After forming the dielectric layer, a layer of photoresist is patterned to define a region to be etched. A first etched region is then formed by removing a first portion of the dielectric layer. That first etched region is filled with a preferably light absorbing sacrificial material having dry etch properties similar to those of the dielectric layer. A second etched region is then formed by removing the sacrificial material and a second portion of the dielectric layer. This improved method may be used to make an integrated circuit that includes a dual damascene interconnect.

Abstract: An improved method of forming an integrated circuit, which includes forming a conductive layer on a substrate, then forming a dielectric layer on the conductive layer. After forming the dielectric layer, a layer of photoresist is patterned to define a region to be etched. A first etched region is then formed by removing a first portion of the dielectric layer. That first etched region is filled with a preferably light absorbing sacrificial material having dry etch properties similar to those of the dielectric layer. A second etched region is then formed by removing the sacrificial material and a second portion of the dielectric layer. This improved method may be used to make an integrated circuit that includes a dual damascene interconnect.

Abstract: A transistor comprising a deposited dual-layer spacer structure and method of fabrication. A polysilicon layer is deposited over a gate dielectric, and is subsequently etched to form the polysilicon gate electrode of the transistor. Next, oxide is deposited over the surface of the gate electrode, followed by deposition of a second dielectric layer. Spacers are then formed adjacent to the gate electrode by etching back the second dielectric layer using a substantially anisotropic etch which etches the second dielectric layer faster than it etches the oxide.

Abstract: A method of forming an interconnection including the steps of depositing a first masking material over a first conductive region of an integrated circuit substrate and depositing a dielectric material over the first masking material. The method also includes forming a via through the dielectric material to expose the first masking material and a second masking material is deposited in a portion of the via. A trench is formed in the dielectric material over a portion of the via and the second masking material is removed from the via. The via is then extended through the first masking material and a conductive material is deposited in the via.

Abstract: A method of forming an interconnection that includes introducing a barrier material in a via of a dielectric to a circuit device on a substrate in such a manner to deposit the barrier material on the circuit device, introducing a seed material into the via in manner that leaves the barrier material overlying the circuit device substantially exposed, substantially removing the barrier material overlying the circuit device, and introducing a conductive material into the via to form the interconnection.

Abstract: An improved method for making an integrated circuit that includes forming a conductive layer on a substrate, then forming a dielectric layer comprising a polymer on the conductive layer. After forming the dielectric layer, a layer of photoresist is patterned to define a region to be etched. An etched region is then formed through the dielectric layer while simultaneously removing the layer of photoresist.

Abstract: A single step electroplating process for interconnect via fill and metal line formation on a semiconductor substrate is disclosed. In this process, a barrier layer is formed onto a surface of a substrate that has at least one via and then a conductive layer is formed onto the barrier layer. Next, a photoresist layer is applied and patterned on top of the conductive layer. The via plugs and metal lines are then deposited on the substrate simultaneously using an electroplating process. After the electroplating process is completed, the photoresist and the conductive layer between the deposited metal lines are removed. The process provides a simple, economical and highly controllable means of forming metal interconnect systems while avoiding the difficulties associated with depositing and patterning metal by traditional semiconductor fabrication techniques.

Abstract: A transistor comprising a deposited dual-layer spacer structure and method of fabrication. A polysilicon layer is deposited over a gate dielectric, and is subsequently etched to form the polysilicon gate electrode of the transistor. Next, oxide is deposited over the surface of the gate electrode, followed by deposition of a second dielectric layer. Spacers are then formed adjacent to the gate electrode by etching back the second dielectric layer using a substantially anisotropic etch which etches the second dielectric layer faster than it etches the oxide.