Abstract: A multiple gate region FET device for forming up to 6 FET devices and method for forming the same, the device including a multiple fin shaped structure comprising a semiconductor material disposed on a substrate; said multiple fin shaped structure comprising substantially parallel spaced apart sidewall portions, each of said sidewall portions comprising major inner and outer surfaces and an upper surface; wherein, each of said surfaces comprises a surface for forming an overlying field effect transistor (FET).

Abstract: A method for forming an opening in a semiconductor device is provided. In one embodiment, a bottom anti-reflective coating (BARC) layer is formed overlying an insulation layer of a substrate. A patterned photoresist layer including at least one opening therein is formed overlying the BARC layer.

Abstract: An improved method of etching very small contact holes through dielectric layers used to separate conducting layers in multilevel integrated circuits formed on semiconductor substrates has been developed. The method uses bi-level ARC coatings in the resist structure and a unique combination of gaseous components in a plasma etching process which is used to dry develop the bi-level resist mask as well as etch through a silicon oxide dielectric layer. The gaseous components comprise a mixture of a fluorine containing gas, such as C4F8, C5F8, C4F6, CHF3 or similar species, an inert gas, such as helium or argon, an optional weak oxidant, such as CO or O2 or similar species, and a nitrogen source, such as N2, N2O, or NH3 or similar species. The patterned masking layer can be used to reliably etch contact holes in silicon oxide layers on semiconductor substrates, where the holes have diameters of about 0.1 micron or less.

Abstract: A method for improving uniformity of stressors of MOS devices is provided. The method includes forming a gate dielectric over a semiconductor substrate, forming a gate electrode on the gate dielectric, forming a spacer on respective sidewalls of the gate electrode and the gate dielectric, forming a recess in the semiconductor adjacent the spacer, and depositing SiGe in the recess to form a SiGe stressor. The method further includes etching the SiGe stressor to improve the uniformity of SiGe stressors.

Abstract: Via hole and trench structures and fabrication methods are disclosed. The structure includes a conductive layer in a dielectric layer, and a via structure in the dielectric layer contacting a portion of a surface of the conductive layer. The via structure includes the conductive liner contacting the portion of the surface of the first conductive layer. A trench structure is formed on the via structure in the dielectric without the conductive liner layer in the trench.

Abstract: A method of forming a silicided gate on a substrate having active regions is provided. The method comprises forming silicide in the active regions and a portion of the gate, leaving a remaining portion of the gate unsilicided; forming a shielding layer over the active regions and gate after the forming step; forming a coating layer over portions of the shielding layer over the active regions; opening the shielding layer to expose the gate, wherein the coating layer protects the portions of the shielding layer over the active regions during the opening step; depositing a metal layer over the exposed gate; and annealing to cause the metal to react with the gate to silicidize at least a part of the remaining portion of the gate.

Abstract: A method for forming stressors in a semiconductor substrate is provided. The method includes providing a semiconductor substrate including a first device region and a second device region, forming shallow trench isolation (STI) regions with a high-shrinkage dielectric material in the first and the second device regions wherein the STI regions define a first active region in the first device region and a second active region in the second device region, forming an insulation mask over the STI region and the first active region in the first device region wherein the insulation mask does not extend over the second device region, and performing a stress-tuning treatment to the semiconductor substrate. The first active region and second active region have tensile stress and compressive stress respectively. An NMOS and a PMOS device are formed on the first and second active regions, respectively.

Abstract: A semiconductor structure having a high-k dielectric and its method of manufacture is provided. A method includes forming a first dielectric layer over the substrate, a metal layer over the first dielectric layer, and a second dielectric layer over the metal layer. A method further includes annealing the substrate in an oxidizing ambient until the three layers form a homogenous high-k dielectric layer. Forming the first and second dielectric layers comprises a non-plasma deposition process such atomic layer deposition (ALD), or chemical vapor deposition (CVD). A semiconductor device having a high-k dielectric comprises an amorphous high-k dielectric layer, wherein the amorphous high-k dielectric layer comprises a first oxidized metal and a second oxidized metal. The atomic ratios of all oxidized metals are substantially uniformly within the amorphous high-k dielectric layer.

Abstract: A novel, in-situ plasma treatment method for eliminating or reducing striations caused by standing waves in a photoresist mask, is disclosed. The method includes providing a photoresist mask on a BARC (bottom anti-reflective coating) layer that is deposited on a feature layer to be etched, etching the BARC layer and the underlying feature layer according to the pattern defined by the photoresist mask, and subjecting the photoresist mask to a typically argon or hydrogen bromide plasma before, after, or both before and after etching of the BARC layer prior to etching of the feature layer. Preferably, the photoresist mask is subjected to the plasma both before and after etching of the BARC layer.

Abstract: Via hole and trench structures and fabrication methods are disclosed. The structure comprises a conductive layer in a dielectric layer, and a via hole in the dielectric layer for exposing a portion of a surface of the conductive layer. A conductive liner covers the exposed surface of the first conductive layer. A trench is formed on the via hole in the dielectric without the conductive liner layer in the trench. Dual damascene structures and fabrications methods are also disclosed. Following the fabrication methods of the via hole and trench structures, a conductive layer is further formed in the via hole and trench structures.

Abstract: Methods and structures for critical dimension or profile measurement are disclosed. The method provides a substrate having periodic openings therein. Material layers are formed in the openings, substantially planarizing a surface of the substrate. A scattering method is applied to the substrate with the material layers for critical dimension (CD) or profile measurement.

Abstract: A method of forming a channel region for a MOSFET device in a strained silicon layer via employment of adjacent and surrounding silicon-germanium shapes, has been developed. The method features simultaneous formation of recesses in a top portion of a conductive gate structure and in portions of the semiconductor substrate not occupied by the gate structure or by dummy spacers located on the sides of the conductive gate structure. The selectively defined recesses will be used to subsequently accommodate silicon-germanium shapes, with the silicon-germanium shapes located in the recesses in the semiconductor substrate inducing the desired strained channel region. The recessing of the conductive gate structure and of semiconductor substrate portions reduces the risk of silicon-germanium bridging across the surface of sidewall spacers during epitaxial growth of the alloy layer, thus reducing the risk of gate to substrate leakage or shorts.

Abstract: A method of removing a silicon nitride or a nitride-based bottom etch stop layer in a copper damascene structure by etching the bottom etch stop layer is disclosed, with the method using a high density, high radical concentration plasma containing fluorine and oxygen to minimize back sputtering of copper underlying the bottom etch stop layer and surface roughening of the low-k interlayer dielectric caused by the plasma.

Abstract: Novel etch stop layers for semiconductor devices and methods of forming thereof are disclosed. In one embodiment, an etch stop layer comprises tensile or compressive stress. In another embodiments, etch stop layers are formed having a first thickness in a first region of a workpiece and at least one second thickness in a second region of a workpiece, wherein the at least one second thickness is different than the first thickness. The etch stop layer may be thicker over top surfaces than over sidewall surfaces. The etch stop layer may be thicker over widely-spaced feature regions and thinner over closely-spaced feature regions.

Abstract: A semiconductor device. A diffusion barrier layer overlies a substrate. An adhesion promoting layer overlies the diffusion barrier layer. A first dielectric layer between the diffusion barrier layer and the adhesion promoting layer comprises at least one via opening through the diffusion barrier layer and the adhesion promoting layer. A second dielectric layer overlies the adhesion promoting layer, comprising a trench opening above the via opening. A metal interconnect fills the via and trench openings.

Abstract: A method of patterning a layer of high-k dielectric material is provided, which may be used in the fabrication of a semiconductor device. A first etch is performed on the high-k dielectric layer. A portion of the high-k dielectric layer being etched with the first etch remains after the first etch. A second etch of the high-k dielectric layer is performed to remove the remaining portion of the high-k dielectric layer. The second etch differs from the first etch. Preferably, the first etch is a dry etch process, and the second etch is a wet etch process. This method further includes a process of plasma ashing the remaining portion of the high-k dielectric layer after the first etch and before the second etch.

Abstract: A process is described for transferring a photoresist pattern into a substrate. In one embodiment a stack comprised of a top photoresist layer, a middle ARC layer, and a bottom hardmask is formed over a gate electrode layer. A line in the photoresist pattern is anisotropically transferred through the ARC and hardmask. Then an isotropic etch to trim the linewidth by 0 to 50 nm per edge is performed simultaneously on the photoresist, ARC and hardmask. This method minimizes the amount of line end shortening to less than three times the dimension trimmed from one line edge. Since a majority of the photoresist layer is retained, the starting photoresist thickness can be reduced by 1000 Angstroms or more to increase process window. The pattern is then etched through the underlying layer to form a gate electrode. The method can also be used to form STI features in a substrate.

Abstract: An integrated apparatus comprises a plasma etching station, a wet cleaning station, a de-gassing station, a thin film deposition station, and a wafer transfer mechanism to automatically index wafers between the stations in a predetermined processing order.

Abstract: A method for removing organic material from an opening in a low k dielectric layer and above a metal layer on a substrate is disclosed. An ozone water solution comprised of one or more additives such as hydroxylamine or an ammonium salt is applied as a spray or by immersion. A chelating agent may be added to protect the metal layer from oxidation. A diketone may be added to the ozone water solution or applied in a gas or liquid phase in a subsequent step to remove any metal oxide that forms during the ozone treatment. A supercritical fluid mixture that includes CO2 and ozone can be used to remove organic residues that are not easily stripped by one of the aforementioned liquid solutions. The removal method prevents changes in the dielectric constant and refractive index of the low k dielectric layer and cleanly removes residues which improve device performance.

Abstract: A method and system for determining the dielectric constant of a low-k dielectric film on a production substrate include measuring the electronic component of the dielectric constant using an ellipsometer, measuring the ionic component of the dielectric constant using an IR spectrometer, measuring the overall dielectric constant using a microwave spectrometer and deriving the dipolar component of the dielectric constant. The measurements and determination are non-contact and may be carried out on a production device that is further processed following the measurements.