Abstract: A field effect transistor (“FET”) is provided which includes a gate stack overlying a single-crystal semiconductor region of a substrate, a pair of first spacers disposed over sidewalls of said gate stack, and a pair of regions consisting essentially of a single-crystal semiconductor alloy which are disposed on opposite sides of the gate stack. Each of the semiconductor alloy regions is spaced a first distance from the gate stack. The source region and drain region of the FET are at least partly disposed in respective ones of the semiconductor alloy regions, such that the source region and the drain region are each spaced a second distance from the gate stack by a first spacer of the pair of first spacers, the second distance being different from the first distance.

Abstract: Disclosed is a p-type field effect transistor (pFET) structure and method of forming the pFET. The pFET comprises embedded silicon germanium in the source/drain regions to increase longitudinal stress on the p-channel and, thereby, enhance transistor performance. Increased stress is achieved by increasing the depth of the source/drain regions and, thereby, the volume of the embedded silicon germanium. The greater depth (e.g., up to 100 nm) of the stressed silicon germanium source/drain regions is achieved by using a double BOX SOI wafer. Trenches are etched through a first silicon layer and first buried oxide layer and then the stressed silicon germanium is epitaxially grown from a second silicon layer. A second buried oxide layer isolates the pFET.

Abstract: A field effect transistor (“FET”) is provided which includes a gate stack overlying a single-crystal semiconductor region of a substrate, a pair of first spacers disposed over sidewalls of said gate stack, and a pair of regions consisting essentially of a single-crystal semiconductor alloy which are disposed on opposite sides of the gate stack. Each of the semiconductor alloy regions is spaced a first distance from the gate stack. The source region and drain region of the FET are at least partly disposed in respective ones of the semiconductor alloy regions, such that the source region and the drain region are each spaced a second distance from the gate stack by a first spacer of the pair of first spacers, the second distance being different from the first distance.

Abstract: The present invention provides a method of forming a semiconducting substrate including the steps of providing an initial structure having first device region comprising a first orientation material and a second device region having a second orientation material; forming a first concentration of lattice modifying material atop the first orientation material; forming a second concentration of the lattice modifying material atop the second orientation material; intermixing the first concentration of lattice modifying material with the first orientation material to produce a first lattice dimension surface and the second concentration of lattice modifying material the second orientation material to produce a second lattice dimension surface; and forming a first strained semiconducting layer atop the first lattice dimension surface and a second strained semiconducting layer atop the second lattice dimension surface.

Abstract: The present invention provides a strained Si directly on insulator (SSDOI) substrate having multiple crystallographic orientations and a method of forming thereof. Broadly, but in specific terms, the inventive SSDOI substrate includes a substrate; an insulating layer atop the substrate; and a semiconducting layer positioned atop and in direct contact with the insulating layer, the semiconducting layer comprising a first strained Si region and a second strained Si region; wherein the first strained Si region has a crystallographic orientation different from the second strained Si region and the first strained Si region has a crystallographic orientation the same or different from the second strained Si region. The strained level of the first strained Si region is different from that of the second strained Si region.

Abstract: A method and structure for fabricating a strained semiconductor on a relaxed SiGe substrate which has dopant diffusion control and defect reduction are provided. Specifically, the dopant diffusion control and defect reduction is achieved in the present invention by providing a SiGe buffer layer between the strained semiconductor and the underlying relaxed SiGe substrate. In accordance with the present invention, the SiGe buffer layer has a Ge content that is less than the Ge content which is present in the relaxed SiGe substrate.

Abstract: Disclosed is an integrated circuit structure and a method of making such a structure that has a substrate and P-type and N-type transistors on the substrate. The N-type transistor extension and source/drain regions comprise dopants implanted into the substrate. The P-type transistor extension and source/drain regions partially include a strained epitaxial silicon germanium, wherein the strained silicon germanium comprises of two layers, with a top layer that is closer to the gate stack than the bottom layer. The strained silicon germanium is in-situ doped and creates longitudinal stress on the channel region.

Abstract: The present invention provides a method for retarding the diffusion of dopants from a first material layer (typically a semiconductor) into an overlayer or vice versa. In the method of the present invention, diffusion of dopants from the first semiconductor into the overlayer or vice versa is retarded by forming a monolayer comprising carbon and oxygen between the two layers. The monolayer is formed in the present invention utilizing a chemical pretreatment process in which a solution including iodine and an alcohol such as methanol is employed.

Abstract: A method of forming a field effect transistor creates shallower and sharper junctions, while maximizing dopant activation in processes that are consistent with current manufacturing techniques. More specifically, the invention increases the oxygen content of the top surface of a silicon substrate. The top surface of the silicon substrate is preferably cleaned before increasing the oxygen content of the top surface of the silicon substrate. The oxygen content of the top surface of the silicon substrate is higher than other portions of the silicon substrate, but below an amount that would prevent epitaxial growth. This allows the invention to epitaxially grow a silicon layer on the top surface of the silicon substrate. Further, the increased oxygen content substantially limits dopants within the epitaxial silicon layer from moving into the silicon substrate.

Abstract: The present invention provides a method of fabricating a SiGe-on-insulator substrate in which lattice engineering is employed to decouple the interdependence between SiGe thickness, Ge fraction and strain relaxation. The method includes providing a SiGe-on-insulator substrate material comprising a SiGe alloy layer having a selected in-plane lattice parameter, a selected thickness parameter and a selected Ge content parameter, wherein the selected in-plane lattice parameter has a constant value and one or both of the other parameters, i.e., thickness or Ge content, have adjustable values; and adjusting one or both of the other parameters to final selected values, while maintaining the selected in-plane lattice parameter. The adjusting is achieved utilizing either a thinning process or a thermal dilution process depending on which parameters are fixed and which are adjustable.

Abstract: A field effect transistor (“FET”) is provided which includes a gate stack overlying a single-crystal semiconductor region of a substrate, a pair of first spacers disposed over sidewalls of said gate stack, and a pair of regions consisting essentially of a single-crystal semiconductor alloy which are disposed on opposite sides of the gate stack. Each of the semiconductor alloy regions is spaced a first distance from the gate stack. The source region and drain region of the FET are at least partly disposed in respective ones of the semiconductor alloy regions, such that the source region and the drain region are each spaced a second distance from the gate stack by a first spacer of the pair of first spacers, the second distance being different from the first distance.

Abstract: Methods for preparing a surface for selective silicon-germanium epitaxy by forming a thin silicon (Si) buffer layer or a thin, low concentration SiGe buffer layer for uniform nucleation, are disclosed.

Abstract: High-quality, metastable SiGe alloys are formed on SOI substrates having an SOI layer of about 500 ? or less, the SiGe layers can remain substantially fully strained compared to identical SiGe layers formed on thicker SOI substrates and subsequently annealed and/or oxidized at high temperatures. The present invention thus provides a method of ‘frustrating’ metastable strained SiGe layers by growing them on thin, clean and high-quality SOI substrates.

Abstract: A method is disclosed for forming a strained Si layer on SiGe, where the SiGe layer has improved thermal conductivity. A first layer of Si or Ge is deposited on a substrate in a first depositing step; a second layer of the other element is deposited on the first layer in a second depositing step; and the first and second depositing steps are repeated so as to form a combined SiGe layer having a plurality of Si layers and a plurality of Ge layers. The respective thicknesses of the Si layers and Ge layers are in accordance with a desired composition ratio of the combined SiGe layer (so that a 1:1 ratio typically is realized with Si and Ge layers each about 10 ? thick). The combined SiGe layer is characterized as a digital alloy of Si and Ge having a thermal conductivity greater than that of a random alloy of Si and Ge.

Abstract: The present invention provides a method for retarding the diffusion of dopants from a first material layer (typically a semiconductor) into an overlayer or vice versa. In the method of the present invention, diffusion of dopants from the first semiconductor into the overlayer or vice versa is retarded by forming a monolayer comprising carbon and oxygen between the two layers. The monolayer is formed in the present invention utilizing a chemical pretreatment process in which a solution including iodine and an alcohol such as methanol is employed.

Abstract: High-quality, metastable SiGe alloys are formed on SOI substrates having an SOI layer of about 500 ? or less, the SiGe layers can remain substantially fully strained compared to identical SiGe layers formed on thicker SOI substrates and subsequently annealed and/or oxidized at high temperatures. The present invention thus provides a method of ‘frustrating’ metastable strained SiGe layers by growing them on thin, clean and high-quality SOI substrates.

Abstract: A method for fabricating substantially relaxed SiGe alloy layers with a reduced planar defect density is disclosed. The method of the present invention includes forming a strained Ge-containing layer on a surface of a Si-containing substrate; implanting ions at or below the Ge-containing layer/Si-containing substrate interface and heating to form a substantially relaxed SiGe alloy layer that has a reduced planar defect density. A substantially relaxed SiGe-on-insulator substrate material having a SiGe layer with a reduced planar defect density as well as heterostructures containing the same are also provided.

Abstract: A method of fabricating a strained semiconductor-on-insulator (SSOI) substrate in which the strained semiconductor is a thin semiconductor layer having a thickness of less than 50 nm that is located directly atop an insulator layer of a preformed silicon-on-insulator substrate is provided. Wafer bonding is not employed in forming the SSOI substrate of the present invention.

Abstract: Structures and methods of manufacturing are disclosed of dislocation free stressed channels in bulk silicon and SOI (silicon on insulator) CMOS (complementary metal oxide semiconductor) devices by gate stress engineering with SiGe and/or Si:C. A CMOS device comprises a substrate of either bulk Si or SOI, a gate dielectric layer over the substrate, and a stacked gate structure of SiGe and/or Si:C having stresses produced at the interfaces of SSi(strained Si)/SiGe or SSi/Si:C in the stacked gate structure. The stacked gate structure has a first stressed film layer of large grain size Si or SiGe over the gate dielectric layer, a second stressed film layer of strained SiGe or strained Si:C over the first stressed film layer, and a semiconductor or conductor such as p(poly)-Si over the second stressed film layer.

Abstract: The invention forms an epitaxial silicon-containing layer on a silicon germanium, patterned strained silicon, or patterned thin silicon-on-insulator surface and avoids creating a rough surface upon which the epitaxial silicon-containing layer is grown. In order to avoid creating the rough surface, the invention first performs a hydrofluoric acid etching process on the silicon germanium, patterned strained silicon, or patterned thin silicon-on-insulator surface. This etching process removes most of oxide from the surface, and leaves a first amount of oxygen (typically 1×1013?1×1015/cm2 of oxygen) on the silicon germanium, patterned strained silicon, or patterned thin silicon-on-insulator surface.