Patent application number | Description | Published |
20080217747 | INTRODUCTION OF METAL IMPURITY TO CHANGE WORKFUNCTION OF CONDUCTIVE ELECTRODES - Semiconductor structures, such as, for example, field effect transistors (FETs) and/or metal-oxide-semiconductor capacitor (MOSCAPs), are provided in which the workfunction of a conductive electrode stack is changed by introducing metal impurities into a metal-containing material layer which, together with a conductive electrode, is present in the electrode stack. The choice of metal impurities depends on whether the electrode is to have an n-type workfunction or a p-type workfunction. The present invention also provides a method of fabricating such semiconductor structures. The introduction of metal impurities can be achieved by codeposition of a layer containing both a metal-containing material and workfunction altering metal impurities, forming a stack in which a layer of metal impurities is present between layers of a metal-containing material, or by forming a material layer including the metal impurities above and/or below a metal-containing material and then heating the structure so that the metal impurities are introduced into the metal-containing material. | 09-11-2008 |
20080220581 | OPTO-THERMAL ANNEALING METHODS FOR FORMING METAL GATE AND FULLY SILICIDED GATE-FIELD EFFECT TRANSISTORS - An opto-thermal annealing method for forming a field effect transistor uses a reflective metal gate so that electrical properties of the metal gate and also interface between the metal gate and a gate dielectric are not compromised when opto-thermal annealing a source/drain region adjacent the metal gate. Another opto-thermal annealing method may be used for simultaneously opto-thermally annealing: (1) a silicon layer and a silicide forming metal layer to form a fully silicided gate; and (2) a source/drain region to form an annealed source/drain region. An additional opto-thermal annealing method may use a thermal insulator layer in conjunction with a thermal absorber layer to selectively opto-thermally anneal a silicon layer and a silicide forming metal layer to form a fully silicide gate. | 09-11-2008 |
20080245658 | METHOD OF FORMING HfSiN METAL FOR n-FET APPLICATIONS - A compound metal comprising HfSiN which is a n-type metal having a workfunction of about 4.0 to about 4.5, preferably about 4.3, eV which is thermally stable on a gate stack comprising a high k dielectric and an interfacial layer. Furthermore, after annealing the stack of HfSiN/high k dielectric/ interfacial layer at a high temperature (on the order of about 1000° C.), there is a reduction of the interfacial layer, thus the gate stack produces a very small equivalent oxide thickness (12 Å classical), which cannot be achieved using TaSiN. | 10-09-2008 |
20080258198 | STABILIZATION OF FLATBAND VOLTAGES AND THRESHOLD VOLTAGES IN HAFNIUM OXIDE BASED SILICON TRANSISTORS FOR CMOS - The present invention provides a metal stack structure that stabilizes the flatband voltage and threshold voltages of material stacks that include a Si-containing conductor and a Hf-based dielectric. This present invention stabilizes the flatband voltages and the threshold voltages by introducing a rare earth metal-containing layer into the material stack that introduces, via electronegativity differences, a shift in the threshold voltage to the desired voltage. Specifically, the present invention provides a metal stack comprising:
| 10-23-2008 |
20080293259 | METHOD OF FORMING METAL/HIGH-k GATE STACKS WITH HIGH MOBILITY - The present invention provides a gate stack structure that has high mobilities and low interfacial charges as well as semiconductor devices, i.e., metal oxide semiconductor field effect transistors (MOSFETs) that include the same. In the semiconductor devices, the gate stack structure of the present invention is located between the substrate and an overlaying gate conductor. The present invention also provides a method of fabricating the inventive gate stack structure in which a high temperature annealing process (on the order of about 800° C.) is employed. The high temperature anneal used in the present invention provides a gate stack structure that has an interface state density, as measured by charge pumping, of about 8×10 | 11-27-2008 |
20090124057 | DAMASCENE GATE FIELD EFFECT TRANSISTOR WITH AN INTERNAL SPACER STRUCTURE - A MOSFET is disclosed that comprises a channel between a source extension and a drain extension, a dielectric layer over the channel, a gate spacer structure formed on a peripheral portion of the dielectric layer, and a gate formed on a non-peripheral portion of the dielectric layer, with at least a lower portion of the gate surrounded by and in contact with an internal surface of the gate spacer structure, and the gate is substantially aligned at its bottom with the channel. One method of forming the MOSFET comprises forming the dielectric layer, the gate spacer structure and the gate contact inside a cavity that has been formed by removing a sacrificial gate and spacer structure. | 05-14-2009 |
20090152642 | SELECTIVE IMPLEMENTATION OF BARRIER LAYERS TO ACHIEVE THRESHOLD VOLTAGE CONTROL IN CMOS DEVICE FABRICATION WITH HIGH-k DIELECTRICS - The present invention provides a semiconductor structure including a semiconductor substrate having a plurality of source and drain diffusion regions located therein, each pair of source and drain diffusion regions are separated by a device channel. The structure further includes a first gate stack of pFET device located on top of some of the device channels, the first gate stack including a high-k gate dielectric, an insulating interlayer abutting the gate dielectric and a fully silicided metal gate electrode abutting the insulating interlayer, the insulating interlayer includes an insulating metal nitride that stabilizes threshold voltage and flatband voltage of the p-FET device to a targeted value and is one of aluminum oxynitride, boron nitride, boron oxynitride, gallium nitride, gallium oxynitride, indium nitride and indium oxynitride. A second gate stack of an nFET devices is located on top remaining device channels, the second gate stack including a high-k gate dielectric and a fully silicided gate electrode located directly atop the high-k gate dielectric. | 06-18-2009 |
20090179279 | METAL GATE ELECTRODE STABILIZATION BY ALLOYING - Stabilized metal gate electrode for complementary metal-oxide-semiconductor (“CMOS”) applications and methods of making the stabilized metal gate electrodes are disclosed. Specifically, the metal gate electrodes are stabilized by alloying wherein the alloy comprises a metal selected from the group consisting of Re, Ru, Pt, Rh, Ni, Al and combinations thereof and an element selected from the group consisting of W, V, Ti, Ta and combinations thereof. | 07-16-2009 |
20090302399 | Using Metal/Metal Nitride Bilayers as Gate Electrodes in Self-Aligned Aggressively Scaled CMOS Devices - The present invention is directed to CMOS structures that include at least one nMOS device located on one region of a semiconductor substrate; and at least one pMOS device located on another region of the semiconductor substrate. In accordance with the present invention, the at least one nMOS device includes a gate stack comprising a gate dielectric, a low workfunction elemental metal having a workfunction of less than 4.2 eV, an in-situ metallic capping layer, and a polysilicon encapsulation layer and the at least one pMOS includes a gate stack comprising a gate dielectric, a high workfunction elemental metal having a workfunction of greater than 4.9 eV, a metallic capping layer, and a polysilicon encapsulation layer. The present invention also provides methods of fabricating such a CMOS structure. | 12-10-2009 |
20100112800 | CMOS STRUCTURE AND METHOD FOR FABRICATION THEREOF USING MULTIPLE CRYSTALLOGRAPHIC ORIENTATIONS AND GATE MATERIALS - Methods for fabricating a CMOS structure use a first gate stack located over a first orientation region of a semiconductor substrate. A second gate material layer is located over the first gate stack and a laterally adjacent second orientation region of the semiconductor substrate. A planarizing layer is located upon the second gate material layer. The planarizing layer and the second gate material layer are non-selectively etched to form a second gate stack that approximates the height of the first gate stack. An etch stop layer may also be formed upon the first gate stack. The resulting CMOS structure may comprise different gate dielectrics, metal gates and silicon gates. | 05-06-2010 |
20110165767 | SELECTIVE IMPLEMENTATION OF BARRIER LAYERS TO ACHIEVE THRESHOLD VOLTAGE CONTROL IN CMOS DEVICE FABRICATION WITH HIGH-k DIELECTRICS - The present invention provides a semiconductor structure including a semiconductor substrate having a plurality of source and drain diffusion regions located therein, each pair of source and drain diffusion regions are separated by a device channel. The structure further includes a first gate stack of pFET device located on top of some of the device channels, the first gate stack including a high-k gate dielectric, an insulating interlayer abutting the gate dielectric and a fully silicided metal gate electrode abutting the insulating interlayer, the insulating interlayer includes an insulating metal nitride that stabilizes threshold voltage and flatband voltage of the p-FET device to a targeted value and is one of aluminum oxynitride, boron nitride, boron oxynitride, gallium nitride, gallium oxynitride, indium nitride and indium oxynitride. A second gate stack of an nFET devices is located on top remaining device channels, the second gate stack including a high-k gate dielectric and a fully silicided gate electrode located directly atop the high-k gate dielectric. | 07-07-2011 |
20120318666 | METHOD AND APPARATUS FOR ELECTROPLATING ON SOI AND BULK SEMICONDUCTOR WAFERS - An electroplating apparatus and method for depositing a metallic layer on the surface of a wafer is provided wherein said apparatus and method do not require physical attachment of an electrode to the wafer. The surface of the wafer to be plated is positioned to face the anode and a plating fluid is provided between the wafer and the electrodes to create localized metallic plating. The wafer may be positioned to physically separate and lie between the anode and cathode so that one side of the wafer facing the anode contains a catholyte solution and the other side of the wafer facing the cathode contains an anolyte solution. Alternatively, the anode and cathode may exist on the same side of the wafer in the same plating fluid. In one example, the anode and cathode are separated by a semi permeable membrane. | 12-20-2012 |