Abstract: An integrated circuit structure combining air-gaps and metal-oxide-metal (MOM) capacitors is provided. The integrated circuit structure includes a semiconductor substrate; a first metallization layer over the semiconductor substrate; first metal features in the first metallization layer; a second metallization layer over the first metallization layer; second metal features in the second metallization layer, wherein the first and the second metal features are non-capacitor features; a MOM capacitor having an area in at least one of the first and the second metallization layers; and an air-gap in the first metallization layer and between the first metal features.

Abstract: A semiconductor contact structure includes a copper plug formed within a dual damascene, single damascene or other opening formed in a dielectric material and includes a composite barrier layer between the copper plug and the sidewalls and bottom of the opening. The composite barrier layer preferably includes an ALD TaN layer disposed on the bottom and along the sides of the opening although other suitable ALD layers may be used. A barrier material is disposed between the copper plug and the ALD layer. The barrier layer may be a Mn-based barrier layer, a Cr-based barrier layer, a V-based barrier layer, a Nb-based barrier layer, a Ti-based barrier layer, or other suitable barrier layers.

Abstract: The structures and methods described above provide mechanisms to improve interconnect reliability and resistivity. The interconnect reliability and resistivity are improved by using a composite barrier layer, which provides good step coverage, good copper diffusion barrier, and good adhesion with adjacent layers. The composite barrier layer includes an ALD barrier layer to provide good step coverage. The composite barrier layer also includes a barrier-adhesion-enhancing film, which contains at least an element or compound that contains Mn, Cr, V, Ti, or Nb to improve adhesion. The composite barrier layer may also include a Ta or Ti layer between the ALD barrier layer and the barrier-adhesion-enhancing layer.

Abstract: A method of forming an interconnect structure of an integrated circuit includes providing a semiconductor substrate; forming a dielectric layer over the semiconductor substrate; forming an opening in the dielectric layer; and forming a copper alloy seed layer in the opening. The copper alloy seed layer physically contacts the dielectric layer. The copper alloy seed layer includes copper and an alloying material. The method further includes filling a metallic material in the opening and over the copper alloy seed layer; performing a planarization to remove excess metallic material over the dielectric layer; and performing a thermal anneal to cause the alloying material in the copper alloy seed layer to be segregated from copper.

Abstract: A semiconductor contact structure includes a copper plug formed within a dual damascene, single damascene or other opening formed in a dielectric material and includes a composite barrier layer between the copper plug and the sidewalls and bottom of the opening. The composite barrier layer preferably includes an ALD TaN layer disposed on the bottom and along the sides of the opening although other suitable ALD layers may be used. A barrier material is disposed between the copper plug and the ALD layer. The barrier layer may be a Mn-based barrier layer, a Cr-based barrier layer, a V-based barrier layer, a Nb-based barrier layer, a Ti-based barrier layer, or other suitable barrier layers.

Abstract: A method of forming an interconnect structure of an integrated circuit includes providing a semiconductor substrate; forming a dielectric layer over the semiconductor substrate; forming an opening in the dielectric layer; and forming a copper alloy seed layer in the opening. The copper alloy seed layer physically contacts the dielectric layer. The copper alloy seed layer includes copper and an alloying material. The method further includes filling a metallic material in the opening and over the copper alloy seed layer; performing a planarization to remove excess metallic material over the dielectric layer; and performing a thermal anneal to cause the alloying material in the copper alloy seed layer to be segregated from copper.

Abstract: A semiconductor interconnection structure is manufactured as follows. First, a substrate with a first dielectric layer and a second dielectric layer is formed. Subsequently, an opening is formed in the second dielectric layer. A thin metal layer and a seed layer are formed in sequence on the surface of the second dielectric layer in the opening, wherein the metal layer comprises at least one metal species having phase segregation property of a second conductor. The wafer of the substrate is subjected to a thermal treatment, by which most of the metal species in the metal layer at a bottom of the opening is diffused to a top surface of the second conductor to form a metal-based oxide layer. Afterwards, the wafer is subjected to planarization, so as to remove the second conductor outside the opening.

Abstract: An apparatus includes an enclosure and a door configured to seal the enclosure. The door includes a plate. A rotational apparatus is disposed over the plate. At least one first member with a first arm extends from a first rib of the first member. At least one second member with a second arm extends from a second rib of the second member. The first and second arms are connected to the rotational apparatus. At least one corner member has a first edge. The first edge has a shape corresponding to a shape of a corner of the frame. The corner member is connected to a first end of the third arm. A second end of the third arm is connected to the rotational apparatus. A sealing material is disposed along a first longitudinal side of the first rib and a second longitudinal side of the second rib.

Abstract: A semiconductor structure and methods for forming the same are provided. The semiconductor structure includes a dielectric layer; a chemical mechanical polish (CMP) stop layer on the dielectric layer; a conductive wiring in the dielectric layer; and a metal cap over the conductive wiring.

Abstract: The manufacture of damascene structures having improved performance, particularly, but not by way of limitation, dual damascene structures is provided. In one embodiment, a substrate having a conductive layer is formed in a first insulating layer. A protective layer is formed above the conductive layer. An etching stop layer is formed above the protective layer and the first insulating layer. A second insulating layer is formed above the etching stop layer. A first patterned photoresist layer is formed above the second insulating layer, the first patterned photoresist layer having a first pattern. The first pattern is etched into the second insulating layer and the etching stop layer to form a first opening. A via plug is filled at least partially in the first opening. An anti-reflective coating (ARC) layer is formed above the second insulating layer. A second patterned photoresist layer is formed above the ARC layer, the second photoresist layer having a second pattern.

Abstract: A method of forming an integrated circuit includes providing a semiconductor substrate, forming a metallization layer over the semiconductor substrate, wherein the metallization layer comprises a metal feature in a low-k dielectric layer and extending from a top surface of the low-k dielectric layer into the low-k dielectric layer, performing a treatment to the low-k dielectric layer to form a hydrophilic top surface, and plating a cap layer on the metal feature in a solution.

Abstract: An interconnection structure for integrated circuits having reduced RC delay and leakage is provided. The interconnection structure includes a first conductive line in a first dielectric layer, a second dielectric layer over the first dielectric layer and the first conductive line, and a dual damascene structure in the second dielectric layer. The dual damascene structure includes a second conductive line and a via between and adjoining the first and the second conductive lines, wherein the second conductive line comprises a first portion directly over and adjoining the via, and a second portion having no underlying and adjoining vias. The second portion has a second width less than a first width of the first portion.

Abstract: An integrated circuit includes a semiconductor substrate, a low-k dielectric layer over the semiconductor substrate, a first opening in the low-k dielectric layer, and a first diffusion barrier layer in the first opening covering the low-k dielectric layer in the first opening, wherein the first diffusion barrier layer has a bottom portion connected to sidewall portions, and wherein the sidewall portions have top surfaces close to a top surface of the low-k dielectric layer. The integrated circuit further includes a conductive line filling the first opening wherein the conductive line has a top surface lower than the top surfaces of the sidewall portions of the diffusion barrier layer, and a metal cap on the conductive line and only within a region directly over the conductive line.

Abstract: An interconnection structure and a fabrication method thereof. A first organic low-k material layer, a stress redistribution layer, a second organic low-k dielectric layer are formed in sequence over a substrate, followed by forming an opening in the first organic low-k material layer, the stress redistribution layer, and the second organic low-k dielectric layer. The opening is then filled with a conductive material to form an interconnection structure. The stress redistribution layer has a heat expansion coefficient closer to that of the substrate, while such heat expansion coefficient differs more significantly from those of the first and second organic low-k material layers.

Abstract: The manufacture of damascene structures having improved performance, particularly, but not by way of limitation, dual damascene structures is provided. In one embodiment, a substrate having a conductive layer is formed in a first insulating layer. A protective layer is formed above the conductive layer. An etching stop layer is formed above the protective layer and the first insulating layer. A second insulating layer is formed above the etching stop layer. A first patterned photoresist layer is formed above the second insulating layer, the first patterned photoresist layer having a first pattern. The first pattern is etched into the second insulating layer and the etching stop layer to form a first opening. A via plug is filled at least partially in the first opening. An anti-reflective coating (ARC) layer is formed above the second insulating layer. A second patterned photoresist layer is formed above the ARC layer, the second photoresist layer having a second pattern.

Abstract: An interconnection structure and a fabrication method thereof. A first organic low-k material layer, a stress redistribution layer, a second organic low-k dielectric layer are formed in sequence over a substrate, followed by forming an opening in the first organic low-k material layer, the stress redistribution layer, and the second organic low-k dielectric layer. The opening is then filled with a conductive material to form an interconnection structure. The stress redistribution layer has a heat expansion coefficient closer to that of the substrate, while such heat expansion coefficient differs more significantly from those of the first and second organic low-k material layers.

Abstract: An interconnection structure and a fabrication method thereof. A first organic low-k material layer, a stress redistribution layer, a second organic low-k dielectric layer are formed in sequence over a substrate, followed by forming an opening in the first organic low-k material layer, the stress redistribution layer, and the second organic low-k dielectric layer. The opening is then filled with a conductive material to form an interconnection structure. The stress redistribution layer has a heat expansion coefficient closer to that of the substrate, while such heat expansion coefficient differs more significantly from those of the first and second organic low-k material layers.

Abstract: An interconnection structure and a fabrication method thereof. A first organic low-k material layer, a stress redistribution layer, a second organic low-k dielectric layer are formed in sequence over a substrate, followed by forming an opening in the first organic low-k material layer, the stress redistribution layer, and the second organic low-k dielectric layer. The opening is then filled with a conductive material to form an interconnection structure. The stress redistribution layer has a heat expansion coefficient closer to that of the substrate, while such heat expansion coefficient differs more significantly from those of the first and second organic low-k material layers.