Abstract: A structure and method for fabricating an e-Fuse device in a semiconductor device is described. A method for fabricating an e-Fuse device includes providing a trench structure including an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. The trench is filled in the anode and cathode regions with a high electromigration (EM) resistant conductive material. The trench in the fuse element region is filled with a low EM resistant conductive material. Another aspect of the invention is an e-Fuse device. The e-Fuse device includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions.

Abstract: A method for fabricating an advanced metal conductor structure is described. A pattern in a dielectric layer is provided. The pattern includes a set of features in the dielectric for a set of metal conductor structures. An adhesion promoting layer is created over the patterned dielectric. A ruthenium layer is deposited over the adhesion promoting layer. Using a physical vapor deposition process, a cobalt layer is deposited over the ruthenium layer. A thermal anneal is performed which reflows the cobalt layer to fill the set of features to form a set of metal conductor structures. In another aspect of the invention, an integrated circuit device is formed using the method.

Abstract: A method providing a high aspect ratio through substrate via in a substrate is described. The through substrate via has vertical sidewalls and a horizontal bottom. The substrate has a horizontal field area surrounding the through substrate via. A first metallic barrier layer is deposited on the sidewalls of the through substrate via. A nitridation process converts a surface portion of the metallic barrier layer to a nitride surface layer. The nitride surface layer enhances the nucleation of subsequent depositions. A first metal layer is deposited to fill the through substrate via. A selective etch creates a recess in the first metal layer in the through substrate via. A second barrier layer is deposited over the recess. A second metal layer is patterned over the second barrier layer filling the recess and creating a contact. Another aspect of the invention is a device produced by the method.

Abstract: An advanced through silicon via structure for is described. The device includes a substrate including integrated circuit devices. A high aspect ratio through substrate via is disposed in the substrate. The through substrate via has vertical sidewalls and a horizontal bottom. The substrate has a horizontal field area surrounding the through substrate via. A metallic barrier layer is disposed on the sidewalls of the through substrate via. A surface portion of the metallic barrier layer has been converted to a nitride surface layer by a nitridation process. The nitride surface layer enhances the nucleation of subsequent depositions. A first metal layer fills the through substrate via and has a recess in an upper portion. A second barrier layer is disposed over the recess. A second metal layer is disposed over the second barrier layer and creates a contact.

Abstract: A method providing a high aspect ratio through substrate via in a substrate is described. The through substrate via has vertical sidewalls and a horizontal bottom. The substrate has a horizontal field area surrounding the through substrate via. A metallic barrier layer is deposited on the sidewalls of the through substrate via. A nitridation process converts a surface portion of the metallic barrier layer to a nitride surface layer. The nitride surface layer enhances the nucleation of subsequent depositions. A first metal layer is deposited to fill a portion of the through substrate via and cover the horizontal field area. A thermal anneal step to reflow a portion of the first metal layer on the horizontal field area into the through substrate via. A second metal layer is deposited over the first metal layer to fill a remaining portion of the through substrate via. Another aspect of the invention is a device created by the method.

Abstract: An integrated circuit device having a substrate including a dielectric layer is patterned with a set of conductive line trenches. Each conductive line trench has parallel vertical sidewalls and a horizontal bottom. A first metal layer fills a first portion of the set of conductive line trenches. The first metal layer is created by an anneal and reflow process of a first metal. A liner which is an alloy of the first metal and a selected element is formed at interfaces of the metal layer and a surface of the dielectric. The liner is created simultaneously with the metal fill by the anneal and reflow process. A wetting layer is disposed on the first metal layer and fills a second portion of the set of conductive line trenches. A second metal layer is disposed on the wetting layer and fills a remainder portion of the set of conductive line trenches.

Abstract: An electrical contact structure for an integrated circuit device is described. A first patterned dielectric layer comprising at least one contact hole, the contact hole including a bottom surface, and sidewalls extending from the bottom surface to a top surface is provided. The bottom surface of the dielectric layer is in contact with a lower layer of the integrated circuit device. A tungsten via is disposed within the at least one contact hole, the tungsten via having a bottom surface in contact with the lower layer and a top surface. A tungsten nitride layer is disposed on the top surface of the tungsten via to repair etch damage done to the tungsten via.

Abstract: An integrated circuit device having a substrate including a dielectric layer is patterned with a set of conductive line trenches. Each conductive line trench has parallel vertical sidewalls and a horizontal bottom. A first metal fills a first portion of the set of conductive line trenches, wherein the metal fill is created by an anneal and reflow process. A liner which is an alloy of the first metal and a selected element is formed at the interfaces of the metal layer and a surface of the dielectric and is created simultaneously with the metal fill by the anneal and reflow process. A second metal layer fills a remainder portion of the set of conductive line trenches.

Abstract: A device relates to a semiconductor device. The semiconductor device includes a narrow-line bamboo microstructure integrated within a metal layer of the semiconductor device and a narrow-line polycrystalline microstructure. The narrow-line polycrystalline microstructure is integrated within the same metal layer as the narrow-line bamboo microstructure.

Abstract: A semiconductor structure containing at least two metal resistor structures having different amounts of nitrogen on the resistor surface is provided. The resulted resistances (and hence resisitivty) of the two metal resistors can be either the same or different. The semiconductor structure may include a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first metal layer portion and a first nitridized metal surface layer having a first nitrogen content. The semiconductor structure further includes a second metal resistor structure located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second metal layer portion and a second nitridized metal surface layer having a second nitrogen content that differs from the first nitrogen content.

Abstract: A semiconductor structure containing at least two metal resistor structures having different resistivities is provided and includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal layer portion and a first nitridized metal surface layer. A second metal resistor structure is located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content, a second metal layer portion and a second nitridized metal surface layer. The second nitrogen content of the second nitridized dielectric surface layer portion differs from the first nitrogen content of the first nitridized dielectric surface layer portion.

Abstract: A semiconductor structure is provided that includes a first metal resistor structure located on a portion of a dielectric-containing substrate. The first metal resistor structure includes, from bottom to top, a first nitridized dielectric surface layer portion having a first nitrogen content, a first metal portion, and a first dielectric capping layer portion. The semiconductor structure of the present application further includes a second metal resistor structure located on a second portion of the dielectric-containing substrate and spaced apart from the first metal resistor structure. The second metal resistor structure includes, from bottom to top, a second nitridized dielectric surface layer portion having a second nitrogen content that differs from the first nitrogen content, a second metal portion, and a second dielectric capping layer portion.

Abstract: In one aspect of the invention, a method to create an advanced through silicon via structure is described. A high aspect ratio through substrate via in a substrate is provided. The through substrate via has vertical sidewalls and a horizontal bottom. A metallic barrier layer is deposited on the sidewalls of the through substrate via. A nitridation process is performed to convert a surface portion of the metallic barrier layer to a nitride surface layer. The nitride surface layer enhances the nucleation of subsequent depositions. A metal is deposited to fill the through substrate via. Another aspect of the invention is a device created by the method.

Abstract: In one aspect of the invention, a method for fabricating an e-Fuse device is described. A trench structure is provided. The trench structure includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions. The trench is provided in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. The trench is filled with copper. An annealing step converts the copper to create a large grained copper structure in the anode and cathode regions and a fine grained copper structure in the fuse element. Another aspect of the invention is an e-Fuse device which includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions.

Abstract: A structure of an e-Fuse device in a semiconductor device is described. The e-Fuse device includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. The anode and cathode regions are comprised of a large grained copper layer and an aspect ratio reducing layer, and the fuse element is comprised of a fine grained copper structure.

Abstract: A structure and method for fabricating an e-Fuse device in a semiconductor device is described A method for fabricating an e-Fuse device includes providing a trench structure including an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. An aspect ratio reducing layer is selectively formed in the anode and cathode regions of the trench while leaving the fuse element region of the trench substantially free of the aspect ratio reducing layer. The trench is filled with copper, both over the aspect ratio reducing layer in the anode and cathode regions and in the fuse element region. The copper is annealed to create a large grained copper structure in the anode and cathode regions and a fine grained copper structure in the fuse element. Another aspect of the invention is an e-Fuse device.

Abstract: An advanced e-Fuse structure is described. An e-Fuse device includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. The anode and cathode regions are comprised of a large grained copper structure and the fuse element is comprised of a fine grained copper structure.

Abstract: A structure and method for fabricating an e-Fuse device in a semiconductor device is described. A method for fabricating an e-Fuse device includes providing a trench structure including an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. The trench is filled in the anode and cathode regions with a high electromigration (EM) resistant conductive material. The trench in the fuse element region is filled with a low EM resistant conductive material. Another aspect of the invention is an e-Fuse device. The e-Fuse device includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions.

Abstract: A structure for an e-Fuse device in a semiconductor device is described. The e-Fuse device includes an anode region, a cathode region and a fuse element which interconnects the anode and cathode regions in a dielectric material on a first surface of a substrate. The fuse element has a smaller cross section and a higher aspect ratio than the anode and cathode regions. The anode and cathode regions are comprised of a high EM-resistant conductive material. The fuse element is comprised of low EM-resistant conductive material.

Abstract: An electrical contact structure for an integrated circuit device is described. A first patterned dielectric layer comprising at least one contact hole, the contact hole including a bottom surface, and sidewalls extending from the bottom surface to a top surface is provided. The bottom surface of the dielectric layer is in contact with a lower layer of the integrated circuit device. A tungsten via is disposed within the at least one contact hole, the tungsten via having a bottom surface in contact with the lower layer and a top surface. A tungsten nitride layer is disposed on the top surface of the tungsten via to repair etch damage done to the tungsten via.