Patent application number | Description | Published |
20090142885 | METHOD FOR PROTECTING POROUS LOW-K DIELECTRIC POST CHEMICAL MECHANICAL PLANARIZATION - A method of forming a semiconductor structure chemically-mechanically polishes (CMP) a semiconductor structure before applying a sealant layer over the porous low-k dielectric. The process of applying the sealant layer is a selective process that causes the sealant to adhere to or deposit onto the porous low-k dielectric and to not adhere to the copper conductors. After the sealant layer is formed, the cap is applied. The parylene layer seals the pores in the low-k dielectric which prevents the low-k dielectric layer from being damaged during the cap pre-cleaning process and also prevents the cap material from penetrating into the low-k dielectric. | 06-04-2009 |
20110291284 | INTERCONNECT STRUCTURE WITH AN OXYGEN-DOPED SiC ANTIREFLECTIVE COATING AND METHOD OF FABRICATION - An interconnect structure is provided that includes at least one patterned and cured photo-patternable low k material located on a surface of a patterned and cured oxygen-doped SiC antireflective coating (ARC). A conductively filled region is located within the at least one patterned and cured photo-patternable low k material and the patterned and cured oxygen-doped SiC ARC. The oxygen-doped SiC ARC, which is a thin layer (i.e., less than 400 angstroms), does not produce standing waves that may degrade the diffusion barrier and the electrically conductive feature that are embedded within the patterned and cured photo-patternable low k dielectric material and, as such, structural integrity is maintained. Furthermore, since a thin oxygen-doped SiC ARC is employed, the plasma etch process time used to open the material stack of the ARC/dielectric cap can be reduced, thus reducing potential plasma damage to the patterned and cured photo-patternable low k material. Also, the oxygen-doped SiC ARC can withstand current BEOL processing conditions. | 12-01-2011 |
20120111825 | AIR GAP INTERCONNECT STRUCTURES AND METHODS FOR FORMING THE SAME - A metal interconnect structure includes at least a pair of metal lines, a cavity therebetween, and a dielectric metal-diffusion barrier layer located on at least one portion of walls of the cavity. After formation of a cavity between the pair of metal lines, the dielectric metal-diffusion barrier layer is formed on the exposed surfaces of the cavity. A dielectric material layer is formed above the pair of metal lines to encapsulate the cavity. The dielectric metal-diffusion barrier layer prevents diffusion of metal and impurities from one metal line to another metal line and vice versa, thereby preventing electrical shorts between the pair of metal lines. | 05-10-2012 |
20130032945 | SELF-ALIGNED FINE PITCH PERMANENT ON-CHIP INTERCONNECT STRUCTURES AND METHOD OF FABRICATION - An interconnect structure and methods for making the same include sidewall portions of an interlevel dielectric layer. The sidewall portions have a width less than a minimum feature size for a given lithographic technology and the width is formed by a thickness of the interlevel dielectric layer when conformally formed on vertical surfaces of a mandrel. The sidewall portions form spaced-apart openings. Conductive structures fill the spaced-apart openings and are separated by the sidewall portions to form single damascene structures. | 02-07-2013 |
20130032949 | SELF-ALIGNED FINE PITCH PERMANENT ON-CHIP INTERCONNECT STRUCTURES AND METHOD OF FABRICATION - An interconnect structure and methods for making the same include sidewall portions of an interlevel dielectric layer. The sidewall portions have a width less than a minimum feature size for a given lithographic technology and the width is formed by a thickness of the interlevel dielectric layer when conformally formed on vertical surfaces of a mandrel. The sidewall portions form spaced-apart openings. Conductive structures fill the spaced-apart openings and are separated by the sidewall portions to form single damascene structures. | 02-07-2013 |
20130043514 | MULTIPHASE ULTRA LOW K DIELECTRIC MATERIAL - A multiphase ultra low k dielectric process incorporating an organo-silicon precursor including an organic porogen, high frequency radio frequency power just above plasma initiation in a PECVD chamber and energy post treatment. A porous SiCOH dielectric material having a k less than 2.7 and a modulus of elasticity greater than 7 GPa. A graded carbon adhesion layer of SiO | 02-21-2013 |
20130333923 | MODULATED COMPOSITIONAL AND STRESS CONTROLLED MULTILAYER ULTRATHIN CONFORMAL SiNx DIELECTRICS USED IN NANO DEVICE FABRICATION - A layer of silicon nitride having a thickness from 0.5 nanometers to 2.4 nanometers is deposited on a substrate. A plasma nitridation process is carried out on the layer. These steps are repeated for a plurality of additional layers of silicon nitride, until a predetermined thickness is attained. Such steps can be used to provide a multilayer silicon nitride dielectric formed on a substrate having an upper surface of dielectric material with Cu and other conductors embedded within, and a plurality of steps. The multilayer silicon nitride dielectric has a plurality of individual layers each having a thickness from 0.5 nanometers to 2.4 nanometers, and the multilayer silicon nitride dielectric conformally covers the steps of the substrate with a conformality of at least seventy percent. A multilayer silicon nitride dielectric, and a multilevel back end of line interconnect wiring structure using same, are also provided. | 12-19-2013 |
20140203336 | ADHESION LAYER AND MULTIPHASE ULTRA-LOW k DIELECTRIC MATERIAL - A dielectric material incorporating a graded carbon adhesion layer whereby the content of C increases with layer thickness and a multiphase ultra low k dielectric comprising a porous SiCOH dielectric material having a k less than 2.7 and a modulus of elasticity greater than 7 GPa is described. A semiconductor integrated circuit incorporating the above dielectric material in interconnect wiring is described and a semiconductor integrated circuit incorporating the above multiphase ultra low k dielectric in a gate stack spacer of a FET is described. | 07-24-2014 |
20150028491 | Improved SiCOH Hardmask with Graded Transition Layers - A structure and method for fabricating an improved SiCOH hardmask with graded transition layers having an improved profile for forming sub-20 nm back end of the line (BEOL) metallized interconnects are provided. In one embodiment, the improved hardmask may be comprised of five layers: an oxide adhesion layer, a graded transition layer, a dielectric layer, an inverse graded transition layer, and an oxide layer. In another embodiment, the improved hardmask may be comprised of four layers; an oxide adhesion layer, a graded transition layer, a dielectric layer, and an oxide layer. In another embodiment, a method of forming an improved hardmask may comprise a continuous five step plasma enhanced chemical vapor deposition (PECVD) process utilizing a silicon precursor, a porogen, and oxygen. In yet another embodiment, a method of forming an improved hardmask may comprise a continuous four step PECVD process utilizing a silicon precursor, a porogen, and oxygen. | 01-29-2015 |