Abstract: A method for making an ultrathin high-k gate dielectric for use in a field effect transistor is provided. The method involves depositing a high-k gate dielectric material on a substrate and forming an ultrathin high-k dielectric by performing a thinning process on the high-k gate dielectric material. The process used to thin the high-k dielectric material can include at least one of any number of processes including wet etching, dry etching (including gas cluster ion beam (GCIB) processing), and hybrid damage/wet etching. In addition to the above, the present invention relates to an ultrathin high-k gate dielectric made for use in a field-effect transistor made by the above method.

Abstract: A semiconductor device such as a complementary metal oxide semiconductor (CMOS) comprising at least one FET that comprises a gate electrode comprising a metal carbide and method of fabrication are provided. The CMOS comprises dual work function metal gate electrodes whereby the dual work functions are provided by a metal and a carbide of a metal.

Abstract: An integrated circuit includes memory cells having array transistors separated by minimum lithographic feature and unsilicided metal bit lines encapsulated by a diffusion barrier while high performance logic transistors may be formed on the same chip without compromise of performance including an effective channel, silicided contacts for low source/drain contact resistance, extension and halo implants for control of short channel effects and a dual work function semiconductor gate having a high impurity concentration and correspondingly thin depletion layer thickness commensurate with state of the art gate dielectric thickness. This structure is achieved by development of thick/tall structures of differing materials using a mask or anti-spacer, preferably of an easily planarized material, and using a similar mask planarized to the height of the structures of differing materials to decouple substrate and gate implantations in the logic transistors.

Abstract: A Deep Trench (DT) capacitor in a semiconductor substrate has an isolation collar formed on trench sidewalls above the DT bottom. An outer plate is formed below the collar. Capacitor dielectric is formed on DT walls below the collar. An node electrode is formed in the DT, recessed below the DT top. The collar is recessed in the DT. A combined poly/counter-recrystallizing species cap is formed over the node electrode with a peripheral strap. The cap may be formed after formed a peripheral divot of a recessed collar, followed by forming an intrinsic poly strap in the divot and doping with a counter-recrystallization species, e.g. Ge, into the node electrode and the strap. Alternatively, the node electrode is recessed followed by codeposition of poly and Ge or another counter-recrystallization species to form the cap and strap.

Abstract: Isolation trenches and capacitor trenches containing vertical FETs (or any prior levels p-n junctions or dissimilar material interfaces) having an aspect ratio up to 60 are filled with a process comprising: applying a spin-on material based on silazane and having a low molecular weight; pre-baking the applied material in an oxygen ambient at a temperature below about 450 deg C.; converting the stress in the material by heating at an intermediate temperature between 450 deg C. and 800 deg C. in an H2O ambient; and heating again at an elevated temperature in an O2 ambient, resulting in a material that is stable up to 1000 deg C., has a compressive stress that may be tuned by variation of the process parameters, has an etch rate comparable to oxide dielectric formed by HDP techniques, and is durable enough to withstand CMP polishing.

Abstract: A carrier for a semiconductor component is provided having passive components integrated in its substrate. The passive components include decoupling components, such as capacitors and resistors. A set of connections is integrated to provide a close electrical proximity to the supported components.

Abstract: In the process of forming a trench capacitor, the conductive strap connecting the center electrode of the capacitor with a circuit element in the substrate, such as the pass transistor of a DRAM cell, is separated from the crystalline substrate material by a barrier layer of silicon carbide formed during the process of etching the material within the trench, such as an oxide collar, using a reactive ion etch process with an etchant gas that contains carbon, such as C4F8.

Abstract: Isolation trenches and capacitor trenches containing vertical FETs (or any prior levels p-n junctions or dissimilar material interfaces) having an aspect ratio up to 60 are filled with a process comprising: applying a spin-on material based on silazane and having a low molecular weight; pre-baking the applied material in an oxygen ambient at a temperature below about 450 deg C.; converting the stress in the material by heating at an intermediate temperature between 450 deg C. and 800 deg C. in an H2O ambient; and heating again at an elevated temperature in an O2 ambient, resulting in a material that is stable up to 1000 deg C., has a compressive stress that may be tuned by variation of the process parameters, has an etch rate comparable to oxide dielectric formed by HDP techniques, and is durable enough to withstand CMP polishing.

Abstract: A process for removing dopant ions from a semiconductor substrate includes exposing the substrate to a non-aqueous organic solvent in liquid and/or vapor form.

Abstract: A 3D microelectronic structure is provided which includes a substrate having at least one opening present therein, the at least one opening having sidewalls which extend to a common bottom wall; and a thermal nitride layer present on at least an upper portion of each sidewall of openings. A method for fabricating the above-mentioned 3D microelectronic structure is also provided. Specifically, the method includes a step of selectively forming a thermal nitride layer on at least an upper portion of each sidewall of an opening formed in a substrate.

Abstract: A capacitor structure having a re-oxide layer on a nitride layer, wherein an interface between the nitride layer and the re-oxide layer includes electron traps. Characteristics of the carrier traps control a voltage output of the device. The thickness of the nitride layer and the re-oxide layer also control the voltage output. The nitride layer and a re-oxide layer form a dielectric capacitor. The dielectric capacitor undergoes a trap filled limit voltage, wherein a consistent voltage is output for a plurality of currents.

Abstract: An improved pitcher-shaped active area for a field effect transistor that, for a given gate length, achieves an increase in transistor on-current, a decrease in transistor serial resistance, and a decrease in contact resistance. The pitcher-shaped active area structure includes at least two shallow trench insulator (STI) structures formed into a substrate that defines an active area structure, which includes a widened top portion with a larger width than a bottom portion. An improved fabrication method for forming the improved pitcher-shaped active area is also described that implements a step to form STI structure divots followed by a step to migrate substrate material into at least portions of the divots, thereby forming a widened top portion of the active area structure. The fabrication method of present invention forms the pitcher-shaped active area without the use of lithography, and therefore, is not limited by the smallest ground rules of lithography tooling.

Abstract: A process for removing dopant ions from a semiconductor substrate includes exposing the substrate to a non-aqueous organic solvent in liquid and/or vapor form.

Abstract: Methods and an apparatus for processing a substrate. A first method comprising: reacting a layer formed on the substrate with a plasma to form a reaction product layer; and simultaneously exposing the reaction product layer to resonant radiation to volatilize the reaction product layer. A second method comprising: performing a plasma enhanced chemical vapor deposition to deposit a precursor layer on a substrate; and simultaneously heating the precursor layer by exposure of the precursor layer to resonant radiation to convert the precursor layer to a deposited layer.

Abstract: A carrier for a semiconductor component is provided having passive components integrated in its substrate. The passive components include decoupling components, such as capacitors and resistors. A set of connections is integrated to provide a close electrical proximity to the supported components.

Abstract: An improved pitcher-shaped active area for a field effect transistor that, for a given gate length, achieves an increase in transistor on-current, a decrease in transistor serial resistance, and a decrease in contact resistance. The pitcher-shaped active area structure includes at least two shallow trench insulator (STI) structures formed into a substrate that defines an active area structure, which includes a widened top portion with a larger width than a bottom portion. An improved fabrication method for forming the improved pitcher-shaped active area is also described that implements a step to form STI structure divots followed by a step to migrate substrate material into at least portions of the divots, thereby forming a widened top portion of the active area structure. The fabrication method of present invention forms the pitcher-shaped active area without the use of lithography, and therefore, is not limited by the smallest ground rules of lithography tooling.

Abstract: An integrated circuit such as a memory chip with embedded logic or a logic array or processor with imbedded large cache memory in which all significant sources of incompatibility between array transistors and high performance logic transistors are resolved. The integrated circuit includes memory cells having array transistors separated by minimum lithographic feature size, F, and memory cell areas or 8-12 F2 and unsilicided metal bit lines encapsulated by a diffusion barrier while high performance logic transistors may be formed on the same chip without compromise of performance including an effective channel length of 0.7 F or less, silicided contacts for low source/drain contact resistance, extension and halo implants for control of short channel effects and a dual work function semiconductor gate having a high impurity concentration and correspondingly thin depletion layer thickness commensurate with state of the art gate dielectric thickness.

Abstract: Structures such as source/drain contacts of improved reliability are enabled by the creation and use of quantum conductive barrier layers at the interface between the electrical contact and the shallow diffusion source/drain region. The quantum conductive layers are preferably nitrides or oxynitrides. The improved structure is preferably part of a transistor structure of an integrated circuit device. The contacts structures are especially useful for devices employing ultra-shallow junctions.

Abstract: Disclosed herein is a method, in an integrated, of forming a high-K node dielectric of a trench capacitor and a trench sidewall device dielectric at the same time. The method includes forming a trench in a single crystal layer of a semiconductor substrate, and forming an isolation collar along a portion of the trench sidewall, wherein the collar has a top below the top of the trench in the single crystal layer. Then, at the same time, a high-K dielectric is formed along the trench sidewall, the high-K dielectric extending in both an upper portion of the trench including above the isolation collar and in a lower portion of the trench below the isolation collar.

Abstract: An integrated circuit includes memory cells having array transistors separated by minimum lithographic feature size, and unsilicided metal bit lines encapsulated by a diffusion barrier while high performance logic transistors may be formed on the same chip without compromise of performance including an effective channel silicided contacts for low source/drain contact resistance, extension and halo implants for control of short channel effects and a dual work function semiconductor gate having a high impurity concentration and correspondingly thin depletion layer thickness commensurate with state of the art gate dielectric thickness. This structure is achieved by of an easily planarized material, and using a similar mask planarized to the height of the structures of differing materials to decouple substrate and gate implantations in the logic transistors.