Abstract: An integrated circuit includes multiple layers. A semiconductor-on-insulator (SOI) wafer can be used to house transistors. Two substrates or wafers can be bonded to form the multiple layers. A strained semiconductor layer can be between a silicon germanium layer and a buried oxide layer. A hydrogen implant can provide a breaking interface to remove a silicon substrate from the silicon germanium layer.

Abstract: A semiconductor substrate is provided having an insulator thereon with a semiconductor layer on the insulator. A deep trench isolation is formed, introducing strain to the semiconductor layer. A gate dielectric and a gate are formed on the semiconductor layer. A spacer is formed around the gate, and the semiconductor layer and the insulator are removed outside the spacer. Recessed source/drain are formed outside the spacer.

Abstract: A method of manufacturing an integrated circuit (IC) utilizes a shallow trench isolation (STI) technique. The shallow trench isolation technique is used in strained silicon (SMOS) process. The liner for the trench is formed from a semiconductor or metal layer which is formed in a selective epitaxial growth (SEG) process. The SEG process can be a CVD or MBE process. Capping layers can be used above the strained silicon layer.

Abstract: A semiconductor on insulator (SOI) device is comprised of a layer of a dielectric material having a perovskite lattice, such as a rare earth scandate. The dielectric material is selected to have an effective lattice constant that enables growth of semiconductor material having a diamond lattice directly on the dielectric. Examples of the rare earth scandate dielectric include gadolinium scandate (GdScO3), dysprosium scandate (DyScO3), and alloys of gadolinium and dysprosium scandate (Gd1?xDyxScO3).

Abstract: Conventional CMOS devices suffer from imbalance because the mobility of holes in the PMOS transistor is less than the mobility of electrons in the NMOS transistor. The use of strained silicon in the channels of CMOS devices further exacerbates the difference in electron and hole mobility, as strained silicon provides a greater increase in electron mobility than hole mobility. However, hole mobility is increased in the SiGe layer underlying the strained silicon layer. Therefore, a more evenly-balanced, high-speed CMOS device is formed by including strained silicon in the NMOS transistor and not in the PMOS transistor of a CMOS device.

Abstract: The present invention enables the production of improved high-reliability, high-density semiconductor devices. The present invention provides the high-density semiconductor devices by decreasing the size of semiconductor device structures, such as gate channel lengths. Short-channel effects are prevented by the use of highly localized halo implant regions formed in the device channel. Highly localized halo implant regions are formed by a tilt pre-amorphization implant and a laser thermal anneal of the halo implant region.

Abstract: According to one exemplary embodiment, a method for integrating first and second metal layers on a substrate to form a dual metal NMOS gate and PMOS gate comprises depositing a dielectric layer over an NMOS region and a PMOS region of the substrate. The method further comprises depositing the first metal layer over dielectric layer. The method further comprises depositing the second metal layer over the first metal layer. The method further comprises implanting nitrogen in the NMOS region of substrate and converting a first portion of the first metal layer into a metal oxide layer and converting a second portion of the first metal layer into metal nitride layer. The method further comprises forming the NMOS gate and the PMOS gate, where the NMOS gate comprises a segment of metal nitride layer and the PMOS gate comprises a segment of the metal oxide layer.

Abstract: An n-type MOSFET (NMOS) is implemented on a substrate having an epitaxial layer of strained silicon formed on a layer of silicon germanium. The MOSFET includes first halo regions formed in the strained silicon layer that extent toward the channel region beyond the ends of shallow source and drain extensions. Second halo regions formed in the underlying silicon germanium layer extend toward the channel region beyond the ends of the shallow source and drain extensions and extend deeper into the silicon germanium layer than the shallow source and drain extensions. The p-type dopant of the first and second halo regions slows the high rate of diffusion of the n-type dopant of the shallow source and drain extensions through the silicon germanium toward the channel region. By counteracting the increased diffusion rate of the n-type dopant in this manner, the shallow source and drain extension profiles are maintained and the risk of degradation by short channel effects is reduced.

Abstract: An exemplary embodiment relates to a method of FinFET channel structure formation. The method can include providing a compound semiconductor layer above an insulating layer, providing a trench in the compound semiconductor layer, and providing a strained semiconductor layer above the compound semiconductor layer and within the trench. The method can also include removing the strained semiconductor layer from above the compound semiconductor layer, thereby leaving the strained semiconductor layer within the trench and removing the compound semiconductor layer to leave the strained semiconductor layer and form the fin-shaped channel region.

Abstract: The present invention provides novel assays for assessing cancerous cell growth. The invention is useful for the identification and validation of oncogenes and tumor suppressors, as well as for the identification and validation of therapeutic compounds for the treatment of cancer.

Abstract: A field effect transistor (FET) is formed on a silicon on insulator (SOI) substrate in the thin silicon layer above the insulating buried oxide layer. The channel region is lightly doped with a first impurity to increase free carrier conductivity of a first type. The source region and the drain region are heavily dopes with the first impurity. A gate and a back gate are positioned along the side of the channel region and extending from the source region and is implanted with a second semiconductor with an energy gap greater than silicon and is implanted with an impurity to increase free carrier flow of a second type.

Abstract: A method of fabricating a semiconductor device comprises forming a gate electrode over a substrate and forming deep amorphous regions within the substrate. And implanting dopants to form deep source/drain regions at a depth less than that of the deep amorphous regions, partially re-crystallizing portions of the deep amorphous regions to reduce their depth, and re-crystallizing the reduced amorphous regions to form activated final source/drain regions.

Abstract: A method of forming a finFET transistor using a sidewall epitaxial layer includes forming a silicon germanium (SiGe) layer above an oxide layer above a substrate, forming a cap layer above the SiGe layer, removing portions of the SiGe layer and the cap layer to form a feature, forming sidewalls along lateral walls of the feature, and removing the feature.

Abstract: A strained silicon p-type MOSFET utilizes a strained silicon channel region formed on a silicon germanium substrate. Silicon germanium regions are formed on the silicon germanium layer adjacent to ends of the strained silicon channel region, and shallow source and drain extensions are implanted in the silicon germanium material. The shallow source and drain extensions do not extend into the strained silicon channel region. By forming the source and drain extensions in silicon germanium material rather than in silicon, source and drain extension distortions caused by the enhanced diffusion rate of boron in silicon are avoided.

Abstract: According to one exemplary embodiment, a method for forming a field-effect transistor on a substrate comprises a step of forming a buffer layer on the substrate, where the buffer layer comprises ALD silicon dioxide. The buffer layer can be formed by utilizing a silicon tetrachloride precursor in an atomic layer deposition process, for example. The buffer layer comprises substantially no pin-hole defects and may have a thickness, for example, that is less than approximately 5.0 Angstroms. The method further comprises forming a high-k dielectric layer over the buffer layer. The high-k dielectric layer may be, for example, hafnium oxide, zirconium oxide, or aluminum oxide. According to this exemplary embodiment, the method further comprises forming a gate electrode layer over the high-k dielectric layer. The gate electrode layer may be polycrystalline silicon, for example.

Abstract: A semiconductor on insulator (SOI) device is comprised of a layer of a dielectric material having a perovskite lattice, such as a rare earth scandate. The dielectric material is selected to have an effective lattice constant that enables growth of semiconductor material having a diamond lattice directly on the dielectric. Examples of the rare earth scandate dielectric include gadolinium scandate (GdScO3), dysprosium scandate (DyScO3), and alloys of gadolinium and dysprosium scandate (Gd1-xDyxScO3).

Abstract: A semiconductor substrate is provided having an insulator thereon with a semiconductor layer on the insulator. A deep trench isolation is formed, introducing strain to the semiconductor layer. A gate dielectric and a gate are formed on the semiconductor layer. A spacer is formed around the gate, and the semiconductor layer and the insulator are removed outside the spacer. Recessed source/drain are formed outside the spacer.

Abstract: An SOI substrate comprises a layer of strained silicon sandwiched between a dielectric layer and a layer of strained silicon. The substrate may be used to form a strained silicon SOI MOSFET having a gate electrode that extends through the silicon germanium layer to a channel region formed in the strained silicon layer. The MOSFET may be formed in a fully depleted state by using a strained silicon layer of appropriate thickness.

Abstract: CMOS devices with balanced drive currents are formed with a PMOS transistor based on SiGe and a deposited high-k gate dielectric. Embodiments including forming a composite substrate comprising a layer of strained Si on a layer of SiGe, forming isolation regions defining a PMOS region and an NMOS region, forming a thermal oxide layer on the strained Si layer, selectively removing the thermal oxide layer and strained Si layer from the PMOS region, depositing a layer of high-k material on the layer of SiGe in the PMOS region and then forming gate electrodes in the PMOS and NMOS regions.

Abstract: A silicon on insulator (SOI) substrate includes a layer of silicon carbide beneath an insulating layer on which semiconductor devices are formed. The silicon carbide layer has a high thermal conductivity and provides beneficial dissipation of thermal energy generated by the devices. The SOI substrate may be formed by a bonding method. SOI MOSFET devices using the SOI substrate are also disclosed.