Abstract: A method comprises measuring an RF voltage and ion current at a wafer during a plasma-enhanced deposition process, determining a sputter rate in response to the RF voltage and ion current measurements, detecting an abnormal condition in response to one of the RF voltage and ion current measurements, and sputter rate, and taking a corrective action in response to detecting an abnormal condition.

Abstract: A MOSFET device pair with improved drive current and a method for producing the same to selectively introduce strain into a respective N-type and P-type MOSFET device channel region, the method including forming a compressive stressed nitride layer on over the P-type MOSFET device and a tensile stressed nitride layer on the N-type MOSFET device followed by forming a PMD layer having a less compressive or tensile stress.

Abstract: Strained channel transistors including a PMOS and NMOS device pair to improve an NMOS device performance without substantially degrading PMOS device performance and method for forming the same, the method including providing a semiconductor substrate; forming strained shallow trench isolation regions in the semiconductor substrate; forming PMOS and NMOS devices on the semiconductor substrate including doped source and drain regions; forming a tensile strained contact etching stop layer (CESL) over the PMOS and NMOS devices; and, forming a tensile strained dielectric insulating layer over the CESL layer.

Abstract: A shallow trench isolation (STI) structure and method of forming the same with reduced stress to improve charge mobility the method including providing a semiconductor substrate comprising at least one patterned hardmask layer overlying the semiconductor substrate; dry etching a trench in the semiconductor substrate according to the at least one patterned hardmask layer; forming one or more liner layers to line the trench selected from the group consisting of silicon dioxide, silicon nitride, and silicon oxynitride; forming one or more layers of trench filling material comprising silicon dioxide to backfill the trench; carrying out at least one thermal annealing step to relax accumulated stress in the trench filling material; carrying out at least one of a CMP and dry etch process to remove excess trench filling material above the trench level; and, removing the at least one patterned hardmask layer.

Abstract: A method of reducing oxide thickness variations in a STI pattern that includes both a dense trench array and a wide trench is described. A first HDP CVD step with a deposition/sputter (D/S) ratio of 9.5 is used to deposit a dielectric layer with a thickness that is 120 to 130% of the shallow trench depth. An etch back is performed in the same CVD chamber with NF3, SiF4 or NF3 and SiF4 to remove about 40 to 50% of the initial dielectric layer. A second HDP CVD step with a D/S ratio of 16 deposits an additional thickness of dielectric layer to a level that is slightly higher than after the first deposition. The etch back and second deposition form a smoother dielectric layer surface which enables a subsequent planarization step to provide filled STI features with a minimal amount of dishing in wide trenches.

Abstract: A test region layout for testing shallow trench isolation gap fill characteristics is disclosed. Each test region further comprises at least one test pattern disposed in an interior portion of the test region. In a preferred embodiment, the test pattern is a square shape or, more preferably, two diametrically opposed “L” shapes which are discontinuous with respect to each other. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: A method of manufacturing a semiconductor device is provided. A semiconductor element is formed on a substrate. The semiconductor element has at least one nickel silicide contact region, an etch stop layer formed over said element, and an insulating layer formed over said etch stop layer. A portion of the etch stop layer immediately over a selected contact region is removed using a process that does not substantially react with the contact region, to form a contact opening. The contact opening is then filled with a conductive material to form a contact.

Abstract: A method is provided for improving Idsat in NMOS and PMOS transistors. A silicon nitride etch stop layer is deposited by a PECVD technique on STI and silicide regions and on sidewall spacers during a MOSFET manufacturing scheme. A dielectric layer is formed on the nitride and then contact holes are fabricated through the dielectric layer and nitride layer to silicide regions and are filled with a metal. For NMOS transistors, silane and NH3 flow rates and a 400° C. temperature are critical in improving NMOS short channel Idsat. Hydrogen content in the nitride is increased by higher NH3 and SiH4 flow rates but does not significantly degrade HCE and Vt. With PMOS transistors, deposition temperature is increased to 550° C. to reduce hydrogen content and improve HCE and Vt stability.

Abstract: A method of manufacturing a semiconductor device is provided. A semiconductor element is formed on a substrate. The semiconductor element has at least one nickel silicide contact region, an etch stop layer formed over said element, and an insulating layer formed over said etch stop layer. A portion of the etch stop layer immediately over a selected contact region is removed using a process that does not substantially react with the contact region, to form a contact opening. The contact opening is then filled with a conductive material to form a contact.

Abstract: Improved processes for depositing dielectric layers by HDP (High Density Plasma) CVD (Chemical Vapor Deposition) are described. One method controls the RF power applied to the side source RF power to be less than about 2500 Watts during dielectric deposition. A second method controls the thickness of the HDP-CVD deposited dielectric layer to be less than between about 2000 and 3000 Angstroms. These methods of HDP-CVD deposition of dielectric layers result in elimination or suppression of plasma induced damage to MOSFET devices and improved gate oxide integrity of MOSFET devices following deposition of dielectric layers by HDP-CVD.

Abstract: Borderless contacts are used in integrated circuits in order to conserve chip real estate. As part of the process for manufacturing borderless contacts, an etch-stopping layer of silicon nitride is first laid over the area that is to be contacted Investigation has now shown that this can lead to damage to the silicon at the edges of the via. The present invention eliminates this damage by introducing a buffer layer between the silicon surface and said silicon nitride layer. Suitable materials for the buffer layer that have been found to be effective include silicon oxide and silicon oxynitride with the latter offering some additional advantages over the former. Experimental data confirming the effectiveness of the buffer layer are provided, together with a process for its manufacture.

Abstract: A process for forming a contact hole opening, featuring the use in situ dry etching, and photoresist removal procedures, used to define the desired contact hole opening; in an overlying hard mask layer, in the dielectric layer, and in an underlying insulator stop layer, has been developed. The process features the initial definition of the contact hole opening, in an overlying hard mask insulator layer, accomplished in a chamber of a dry etch tool, followed by removal of an overlying, contact hole defining photoresist shape, performed in situ, in the same dry etch chamber. The contact hole opening is then transferred to the dielectric layer via a selective dry etch procedure, performed in situ, in the dry etch chamber, using the overlying hard mask insulator layer as an etch mask.

Abstract: Borderless contacts are used in integrated circuits in order to conserve chip real estate. As part of the process for manufacturing borderless contacts, an etch-stopping layer of silicon nitride is first laid over the area that is to be contacted Investigation has now shown that this can lead to damage to the silicon at the edges of the via. The present invention eliminates this damage by introducing a buffer layer between the silicon surface and said silicon nitride layer. Suitable materials for the buffer layer that have been found to be effective include silicon oxide and silicon oxynitride with the latter offering some additional advantages over the former. Experimental data confirming the effectiveness of the buffer layer are provided, together with a process for its manufacture.

Abstract: A process for forming a composite, interlevel dielectric, (ILD), layer, for MOSFET devices, has been developed. The composite ILD layer is comprised with an underlying, undoped silicon glass layer, providing the material needed to fill the narrow spaces between polysilicon gate structures of the MOSFET devices. A P2O5 doped, insulator layer, is next formed on the underlying, undoped silicon glass layer, to provide a mobile ion gettering property. An overlying, undoped silicon glass layer is then deposited and subjected to a chemical mechanical polishing procedure, resulting in the desired planar top surface topography, for the composite ILD layer.

Abstract: A method of forming a composite dielectric layer comprising the following steps. A structure having at least two semiconductor structures separated by a gap therebetween is provided. A first dielectric layer is formed over the structure, the two semiconductor structures and within the gap between the two semiconductor structures to a thickness as least as high as the top of the semiconductor structures by a first high density plasma (HDP) process. The first HDP process having a first high bias RF power, a low first deposition: sputter ratio and a first chucking bias voltage. A second dielectric layer is then formed over the first dielectric layer by a second HDP process to form the composite dielectric layer. The second HDP process having: a second bias RF power that is less than the first bias RF power; a second deposition: sputter ratio that is greater than the first deposition: sputter ratio; and a second chucking bias voltage that is zero.

Abstract: Borderless contacts are used in integrated circuits in order to conserve chip real estate. As part of the process for manufacturing borderless contacts, an etch-stopping layer of silicon nitride is first laid over the area that is to be contacted. Investigation has now shown that this can lead to damage to the silicon at the edges of the via. The present invention eliminates this damage by introducing a buffer layer between the silicon surface and said sidon nitride layer. Suitable materials for the buffer layer that have been found to be infective include silicon oxide and silicon oxynitride with the latter offering some ditional advantages over the former. Experimental data confirming the effectiveness of the buffer layer are provided, together with a process for its manufacture.

Abstract: A method for shallow trench isolation formation having a thick un-biased HDP USG liner layer to reduce HDP-CVD induced defects is described. Trenches are etched through an etch stop layer into a semiconductor substrate. The semiconductor substrate is thermally oxidized to form a thermal liner layer within the isolation trenches. The isolation trenches are filled using a high density plasma chemical vapor deposition process (HDP-CVD) having a deposition component and a sputtering component wherein the HDP-CVD process comprises: first depositing a first liner layer overlying the thermal liner layer wherein no bias power is supplied during the first depositing step and wherein the first liner layer has a thickness of between 200 and 400 Angstroms, second depositing a second liner layer using low bias power, and third depositing a gap filling layer overlying the second liner layer to fill the isolation trenches. The gap filling layer is polished back overlying the etch stop layer.

Abstract: A method for significantly reducing plasma damage during the deposition of inter-layer dielectric (ILD) gapfills on topographic substrates by high density plasma chemical vapor deposition (HDP-CVD). The method can also be applied to the deposition of dielectric layers on silicon oxide covered substrates. The method provides a modification of current state of the art practices in HDP-CVD by a novel variation in the RF input power to the plasma processing chamber during certain portions of the processing cycle. Specifically, top/side RF power is reduced from 3000W/4000W to 1300W/3100W during the heat-up portion of the cycle and plasma lift is eliminated during the wafer release and lift portion of the cycle by turning off the 1000W/2000W top/side RF power. A method for determining the degree of plasma induced damage by measurement of a flatband voltage is also provided.

Abstract: A method for forming upon a substrate employed within a microelectronics fabrication a dieletric layer with improved physical properties. There is first provided a substrate. There is then formed over the substrate a series of lines which constitute a patterned microelectronics layer. There is then formed over the patterned microelectronics layer and substrate a conformal dielectric layer. There is then formed over the substrate a second dielectric layer. There is then formed over the substrate a third dielectric layer formed of silicon oxide dielectric material employing high density plasma chemical vapor deposition (HDP-CVD) to complete a composite inter-level metal dielectric (IMD) layer. A fourth dielectric layer formed employing silicon containing dielectric material may be formed over the substrate and third dielectric layer to complete an inter-level metal dielectric (IMD) layer.

Abstract: A method for forming a series of patterned planarized aperture fill layers within a series of apertures within a topographic substrate layer employed within a microelectronics fabrication. There is first provided a topographic substrate layer employed within a microelectronics fabrication, where the topographic substrate layer comprises a series of mesas of substantially equivalent height but of differing widths and the series of mesas is separated by a series of apertures. There is then formed upon the topographic substrate layer a blanket first aperture fill layer. The blanket first aperture fill layer is formed employing a first simultaneous deposition and sputter method.