Abstract: A method of reducing the contact resistance of metal silicides to the p+ silicon area or the n+ silicon area of the substrate comprising: (a) forming a metal germanium (Ge) layer over a silicon-containing substrate, wherein said metal is selected from the group consisting of Co, Ti, Ni and mixtures thereof; (b) optionally forming an oxygen barrier layer over said metal germanium layer; (c) annealing said metal germanium layer at a temperature which is effective in converting at least a portion thereof into a substantially non-etchable metal silicide layer, while forming a Si—Ge interlayer between said silicon-containing substrate and said substantially non-etchable metal silicide layer; and (d) removing said optional oxygen barrier layer and any remaining alloy layer. When a Co or Ti alloy is employed, e.g.

Abstract: In an interconnect structure of an integrated circuit, a diffusion barrier film in a damascene structure is formed of a film having the composition TaNx, where x is greater than 1.2 and with a thickness of 0.5 to 5 nm.

Abstract: A method of producing electrical contacts having reduced interface roughness as well as the electrical contacts themselves are disclosed herein. The method of the present invention comprises (a) forming an alloy layer having the formula MX, wherein M is a metal selected from the group consisting of Co and Ni and X is an alloying additive, over a silicon-containing substrate; (b) optionally forming an optional oxygen barrier layer over said alloy layer; (c) annealing said alloy layer at a temperature sufficient to form a MXSi layer in said structure; (d) removing said optional oxygen barrier layer and any remaining alloy layer; and optionally (e) annealing said MXSi layer at a temperature sufficient to form a MXSi2 layer in said structure.

Abstract: In one embodiment of the invention, source and drain regions are formed as well as source and drain contact regions. Thereafter source and drain extension regions are formed. In another embodiment, elevated source and drain regions are formed as well as source and drain extension regions. Thereafter source and drain contact regions are formed at a temperature up to about 600° C. and an annealing time of up to about one minute.

Abstract: A method of fabricating a complementary metal oxide semiconductor (CMOS) device, wherein the method comprises forming a first well region in a semiconductor substrate for accommodation of a first type semiconductor device; forming a second well region in the semiconductor substrate for accommodation of a second type semiconductor device; shielding the first type semiconductor device with a mask; depositing a first metal layer over the second type semiconductor device; performing a first salicide formation on the second type semiconductor device; removing the mask; depositing a second metal layer over the first and second type semiconductor devices; and performing a second salicide formation on the first type semiconductor device. The method requires only one pattern level and it eliminates pattern overlay as it also simplifies the processes to form different silicide material over different devices.

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: A method of fabricating a complementary metal oxide semiconductor (CMOS) device, wherein the method comprises forming a first well region in a semiconductor substrate for accommodation of a first type semiconductor device; forming a second well region in the semiconductor substrate for accommodation of a second type semiconductor device; shielding the first type semiconductor device with a mask; depositing a first metal layer over the second type semiconductor device; performing a first salicide formation on the second type semiconductor device; removing the mask; depositing a second metal layer over the first and second type semiconductor devices; and performing a second salicide formation on the first type semiconductor device. The method requires only one pattern level and it eliminates pattern overlay as it also simplifies the processes to form different silicide material over different devices.

Abstract: The present invention provides a complementary metal oxide semiconductor integration process whereby a plurality of silicided metal gates are fabricated atop a gate dielectric. Each silicided metal gate that is formed using the integration scheme of the present invention has the same silicide metal phase and substantially the same height, regardless of the dimension of the silicide metal gate. The present invention also provides various methods of forming a CMOS structure having silicided contacts in which the polySi gate heights are substantially the same across the entire surface of a semiconductor structure.

Abstract: Silicide is introduced into the gate region of a CMOS device through different process options for both conventional and replacement gate types processes. Placement of silicide in the gate itself, introduction of the silicide directly in contact with the gate dielectric, introduction of the silicide as a fill on top of a metal gate all ready in place, and introduction the silicide as a capping layer on polysilicon or on the existing metal gate, are presented. Silicide is used as an option to connect between PFET and NFET devices of a CMOS structure. The processes protect the metal gate while allowing for the source and drain silicide to be of a different silicide than the gate silicide. A semiconducting substrate is provided having a gate with a source and a drain region. A gate dielectric layer is deposited on the substrate, along with a metal gate layer. The metal gate layer is then capped with a silicide formed on top of the gate, and conventional formation of the device then proceeds.

Abstract: An integrated circuit is provided including an FET gate structure formed on a substrate. This structure includes a gate dielectric on the substrate, and a metal nitride layer overlying the gate dielectric and in contact therewith. This metal nitride layer is characterized as MNx, where M is one of W, Re, Zr, and Hf, and x is in the range of about 0.7 to about 1.5. Preferably the layer is of WNx, and x is about 0.9. Varying the nitrogen concentration in the nitride layer permits integration of different FET characteristics on the same chip. In particular, varying x in the WNx layer permits adjustment of the threshold voltage in the different FETs. The polysilicon depletion effect is substantially reduced, and the gate structure can be made thermally stable up to about 1000° C.

Abstract: Very low resistance, scaled in MOSFET devices are formed by employing thin silicidation-stop extension that act both as a silicidation “stop” barriers and as thin interface layers between source/drain silicide regions and channel region of the MOSFET. By acting as silicidation stops, the silicidation-stop extensions confine silicidation, and are not breached by source/drain silicide. This permits extremely thin, highly-doped silicidation-stop extensions to be formed between the silicide and the channel, providing an essentially ideal, low series resistance interface between the silicide and the channel.

Abstract: A method (and resulting structure) for fabricating a silicide for a semiconductor device, includes depositing a metal or an alloy thereof on a silicon substrate, reacting the metal or the alloy to form a first silicide phase, etching any unreacted metal, depositing a silicon cap layer over the first silicide phase, reacting the silicon cap layer to form a second silicide phase, for the semiconductor device, and etching any unreacted silicon. The substrate can be either a silicon-on-insulator (SOI) substrate or a bulk silicon substrate.

Abstract: A method of fabricating hafnium oxide and/or zirconium oxide films is provided. The methods include providing a mixture of Hf and/or Zr alkoxide dissolved, emulsified or suspended in a liquid; vaporizing at least the alkoxide and depositing the vaporized component at a temperature of greater than 400° C. The resultant film is dense, microcrystalline and is capable of self-passivation when treated in a hydrogen plasma or forming gas anneal.

Abstract: A method for plating copper conductors on an electronic substrate and devices formed are disclosed. In the method, an electroplating copper bath that is filled with an electroplating solution kept at a temperature between about 0° C. and about 18° C. is first provided. A copper layer on the electronic substrate immersed in the electroplating solution is then plated either in a single step or in a dual-step deposition process. The dual-step deposition process is more suitable for depositing copper conductors in features that have large aspect ratios, such as a via hole in a dual damascene structure having an aspect ratio of diameter/depth of more than ? or as high as 1/10. Various electroplating parameters are utilized to provide a short resistance transient in either the single step deposition or the dual-step deposition process.

Abstract: A method (and structure) of forming a vertically-self-aligned silicide contact to an underlying SiGe layer, includes forming a layer of silicon of a first predetermined thickness on the SiGe layer and forming a layer of metal on the silicon layer, where the metal layer has a second predetermined thickness. A thermal annealing process at a predetermined temperature then forms a silicide of the silicon and metal, where the predetermined temperature is chosen to substantially preclude penetration of the silicide into the underlying SiGe layer.

Abstract: Disclosed is a method for making a metal gate for a FET, wherein the metal gate comprises at least some material deposited by electroplating as well as an FET device comprising a metal gate that is at least partially plated. Further disclosed is a method for making a metal gate for a FET wherein the metal gate comprises at least some plated material and the method comprises the steps of: selecting a substrate having a top surface and a recessed region; conformally depositing a thin conductive seed layer on the substrate; and electroplating a filler gate metal on the seed layer to fill and overfill the recessed region.

Abstract: The present invention provides metallic films containing a Group IVB or VB metal, silicon and optionally nitrogen by utilizing atomic layer deposition (ALD). In particularly, the present invention provides a low temperature thermal ALD method of forming metallic silicides and a plasma-enhanced atomic layer deposition (PE-ALD) method of forming metallic silicon nitride film. The methods of the present invention are capable of forming metallic films having a thickness of a monolayer or less on the surface of a substrate. The metallic films provided in the present invention can be used for contact metallization, metal gates or as a diffusion barrier.

Abstract: Field effect transistor (FET), integrated circuit (IC) chip including the FETs and a method of forming the FETs. The FETs have a device channel and a gate above the device channel with a doped source/drain extension at said each end of the thin channel. A portion of a low resistance material layer (e.g., a silicide layer) is disposed on source/drain extensions. The portions on the doped extensions laterally form a direct contact with the doped source/drain extension. Any low resistance material layer on the gate is separated from the low resistance material portions on the source/drain extensions.

Abstract: A CMOS silicide metal integration scheme that allows for the incorporation of silicide contacts (S/D and gates) and metal silicide gates using a self-aligned process (salicide) as well as one or more lithography steps is provided. The integration scheme of the present invention minimizes the complexity and cost associated with fabricating a CMOS structure containing silicide contacts and silicide gate metals.

Abstract: A structure and method for a metal replacement gate of a high performance device is provided. A sacrificial gate structure is first formed on an etch stop layer provided on a semiconductor substrate. A pair of spacers is provided on sidewalls of the sacrificial gate structure. The sacrificial gate structure is then removed, forming an opening. Subsequently, a metal gate including an first layer of metal such as tungsten, a diffusion barrier such as titanium nitride, and a second layer of metal such as tungsten is formed in the opening between the spacers.