Abstract: A dual-damascene process where first alternate ILDs are made of a first material and second alternate ILDs are made of a second material. Each material is etchable at a faster rate than the other in the presence of different etchant such as for an organic polymer and an inorganic low k material. This allows the ILDs to be deposited alternately on one another without an etchant stop layer thereby reducing capacitance.

Abstract: The present invention discloses a method including providing a substrate; forming a dielectric over the substrate, the dielectric having a k value of about 2.5 or lower, the dielectric having a Young's modulus of elasticity of about 15 GigaPascals or higher; forming an opening in the dielectric; and forming a conductor in the opening. The present invention further discloses a structure including a substrate; a dielectric located over the substrate, the dielectric having a k value of 2.5 or lower, the dielectric having a Young's modulus of elasticity of about 15 GigaPascals or higher; an opening located in the dielectric; and a conductor located in the opening.

Abstract: A method for selecting and forming a low-k, relatively high E porous ceramic film in a semiconductor device is described. A ceramic material is selected having a relatively high Young's modulus and relatively lower dielectric constant. The k is reduced by making the film porous.

Abstract: A low-k dielectric sacrificial material is formed within a microelectronic structure covered with a suitable porous or low density permeable material. At an appropriate time, the underlying sacrificial material is decomposed and diffused away through the overlying permeable material. As a result, at least one void is created, contributing to desirable dielectric characteristics.

Abstract: The present invention discloses a method including providing a substrate; forming a dielectric over the substrate, the dielectric having a k value of about 2.5 or lower, the dielectric having a Young's modulus of elasticity of about 15 GigaPascals or higher; forming an opening in the dielectric; and forming a conductor in the opening. The present invention further discloses a structure including a substrate; a dielectric located over the substrate, the dielectric having a k value of 2.5 or lower, the dielectric having a Young's modulus of elasticity of about 15 GigaPascals or higher; an opening located in the dielectric; and a conductor located in the opening.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer, initially comprising a porous matrix and a porogen, is formed. Subsequent to other processing treatments, the porogen is decomposed and removed from at least a portion of the porous matrix, leaving voids defined by the porous matrix in areas previously occupied by the porogen. The resultant structure has a desirably low k value as a result of the porosity and materials comprising the porous matrix and porogen. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: A die is provided with an interconnect, and the grain structure of the interconnect is adapted to reduce electron scattering.

Abstract: A dual-damascene process where first alternate ILDs are made of a first material and second alternate ILDs are made of a second material. Each material is etchable at a faster rate than the other in the presence of different etchant such as for an organic polymer and an inorganic low k material. This allows the ILDs to be deposited alternately on one another without an etchant stop layer thereby reducing capacitance.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer, initially comprising a porous matrix and a porogen, is formed. Subsequent to other processing treatments, the porogen is decomposed and removed from at least a portion of the porous matrix, leaving voids defined by the porous matrix in areas previously occupied by the porogen. The resultant structure has a desirably low k value as a result of the porosity and materials comprising the porous matrix and porogen. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer comprising a porous matrix, as well as a porogen in certain variations, is formed adjacent a sacrificial dielectric layer. Subsequent to other processing treatments, a portion of the sacrificial dielectric layer is decomposed and removed through a portion of the porous matrix using supercritical carbon dioxide leaving voids in positions previously occupied by portions of the sacrificial dielectric layer. The resultant structure has a desirably low k value as a result of the voids and materials comprising the porous matrix and other structures. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer, initially comprising a porous matrix and a porogen, is formed. Subsequent to other processing treatments, the porogen is decomposed and removed from at least a portion of the porous matrix, leaving voids defined by the porous matrix in areas previously occupied by the porogen. The resultant structure has a desirably low k value as a result of the porosity and materials comprising the porous matrix and porogen. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: An inter-layer dielectric structure and method of making such structure are disclosed. A composite dielectric layer comprising a porous matrix, as well as a porogen in certain variations, is formed adjacent a sacrificial dielectric layer. Subsequent to other processing treatments, a portion of the sacrificial dielectric layer is decomposed and removed through a portion of the porous matrix using supercritical carbon dioxide leaving voids in positions previously occupied by portions of the sacrificial dielectric layer. The resultant structure has a desirably low k value as a result of the voids and materials comprising the porous matrix and other structures. The composite dielectric layer may be used in concert with other dielectric layers of varying porosity, dimensions, and material properties to provide varied mechanical and electrical performance profiles.

Abstract: An embodiment of the present invention includes a method to form an air gap in a multi-layer structure. A dual damascene structure is formed on a substrate. The dual damascene structure has a metallization layer, a barrier layer, a sacrificial layer, and a hard mask layer. The sacrificial layer is made of a first sacrificial material having substantial thermal stability and decomposable by an electron beam. The sacrificial layer is removed by the electron beam to create the air gap between the barrier layer and the hard mask layer.

Abstract: An ultraviolet sensitive material may be formed within a semiconductor structure covered with a suitable hard mask. At an appropriate time, the underlying ultraviolet sensitive material may be exposed to ultraviolet radiation, causing the material to exhaust through the overlying hard mask. As a result, an air gap may be created having desirable characteristics as a dielectric.

Abstract: A dielectric material is strengthened by bonding a metal component to the dielectric matrix. The metal component may be a metal oxide or metal oxide precursor. The metal component may be deposited on the substrate with the dielectric material, or sol-gel chemistry may be used and the liquid solution spin-coated on a substrate.

Abstract: Method and structure for passivating conductive material are disclosed. Atomic layer deposition of a thin passivation layer such as titanium nitride upon a conductive layer comprising a material such as copper, in the presence of a dielectric material not conductive to surface reaction with gaseous precursors used in the deposition schema, facilitates highly selective and accurate passivation which may improve electromigration performance, minimize leakage current to other conductive layers, and streamline process steps.

Abstract: An embodiment of the present invention includes a method to form an air gap in a multi-layer structure. A dual damascene structure is formed on a substrate. The dual damascene structure has a metallization layer, a barrier layer, a sacrificial layer, and a hard mask layer. The sacrificial layer is made of a first sacrificial material having substantial thermal stability and decomposable by an electron beam. The sacrificial layer is removed by the electron beam to create the air gap between the barrier layer and the hard mask layer.

Abstract: A dielectric material is strengthened by bonding a metal component to the dielectric matrix. The metal component may be a metal oxide or metal oxide precursor. The metal component may be deposited on the substrate with the dielectric material, or sol-gel chemistry may be used and the liquid solution spin-coated on a substrate.

Abstract: Described is a method and apparatus for forming interconnects with a metal-metal oxide electromigration barrier and etch-stop. In one embodiment of the invention, the method includes depositing a metal layer on the top of a planarized interconnect layer, the interconnect layer having an interlayer dielectric (ILD) with a top that is planar with the top of an electrically conductive interconnect. In one embodiment of the invention, the method includes reacting the metal layer with the ILD to form a metal oxide layer on the top of the ILD. At the same time, the metal layer will not be significantly oxidized by the electrically conductive interconnect, thus forming a metal barrier on the electrically conductive interconnect to improve electromigration performance. The metal barrier and metal oxide layer together comprise a protective layer. A second ILD may be subsequently formed on the protective layer, and the protective layer may act an etch-stop during a subsequent etch of the second ILD.

Abstract: Described is a method and apparatus for altering the top surface of a metal interconnect. In one embodiment of the invention, a metal interconnect and a barrier layer are formed into an interlayer dielectric (ILD) and the metal interconnect and the barrier layer are planarized to the top of the ILD. The top surfaces of the metal interconnect, the barrier layer, and the ILD are altered with a second metal to form an electromigration barrier. In one embodiment of the invention, the second metal is prevented from contaminating the electrical resistivity of the metal interconnect.