Abstract: A method for forming a field effect transistor device includes forming an oxide layer on a substrate, forming a dielectric layer on the oxide layer, forming a first TiN layer on the dielectric layer, forming a metallic layer on the first layer, forming a second TiN layer on the metallic layer, removing a portion of the first TiN layer, the metallic layer, and the second TiN layer to expose a portion of the dielectric layer, forming a layer of stoichiometric TiN on the exposed portion of the dielectric layer and the second TiN layer, heating the device, and forming a polysilicon layer on the device.

Abstract: Methods for fabricating gate electrode/high-k dielectric gate structures having an improved resistance to the growth of silicon dioxide (oxide) at the dielectric/silicon-based substrate interface. In an embodiment, a method of forming a transistor gate structure comprises: incorporating nitrogen into a silicon-based substrate proximate a surface of the substrate; depositing a high-k gate dielectric across the silicon-based substrate; and depositing a gate electrode across the high-k dielectric to form the gate structure. In one embodiment, the gate electrode comprises titanium nitride rich in titanium for inhibiting diffusion of oxygen.

Abstract: A field effect transistor device includes a first gate stack portion including a dielectric layer disposed on a substrate, a first TiN layer disposed on the dielectric layer, a metallic layer disposed on the dielectric layer, and a second TiN layer disposed on the metallic layer, a first source region disposed adjacent to the first gate stack portion, and a first drain region disposed adjacent to the first gate stack portion.

Abstract: Methods for fabricating gate electrode/high-k dielectric gate structures having an improved resistance to the growth of silicon dioxide (oxide) at the dielectric/silicon-based substrate interface. In an embodiment, a method of forming a transistor gate structure comprises: incorporating nitrogen into a silicon-based substrate proximate a surface of the substrate; depositing a high-k gate dielectric across the silicon-based substrate; and depositing a gate electrode across the high-k dielectric to form the gate structure. In one embodiment, the gate electrode comprises titanium nitride rich in titanium for inhibiting diffusion of oxygen.

Abstract: A method of forming fin field effect transistor (finFET) devices includes forming a plurality of semiconductor fins over a buried oxide (BOX) layer; performing a nitrogen implant so as to formed nitrided regions in a upper portion of the BOX layer corresponding to regions between the plurality of semiconductor fins; forming a gate dielectric layer over the semiconductor fins and the nitrided regions of the upper portion of the BOX layer; and forming one or more gate electrode materials over the gate dielectric layer; wherein the presence of the nitrided regions of upper portion of the BOX layer prevents oxygen absorption into the gate dielectric layer as a result of thermal processing.

Abstract: Adjustment of a switching threshold of a field effect transistor including a gate structure including a Hi-K gate dielectric and a metal gate is achieved and switching thresholds coordinated between NFETs and PFETs by providing fixed charge materials in a thin interfacial layer adjacent to the conduction channel of the transistor that is provided for adhesion of the Hi-K material, preferably hafnium oxide or HfSiON, depending on design, to semiconductor material rather than diffusing fixed charge material into the Hi-K material after it has been applied. The greater proximity of the fixed charge material to the conduction channel of the transistor increases the effectiveness of fixed charge material to adjust the threshold due to the work function of the metal gate, particularly where the same metal or alloy is used for both NFETs and PFETs in an integrated circuit; preventing the thresholds from being properly coordinated.

Abstract: A method includes providing an SOI substrate including a layer of silicon disposed atop a layer of an oxide, the layer of an oxide being disposed atop the semiconductor substrate; forming a deep trench having a sidewall extending through the layer of silicon and the layer of an oxide and into the substrate; depositing a continuous spacer on the sidewall to cover the layer of silicon, the layer of an oxide and a part of the substrate; depositing a first conformal layer of a conductive material throughout the inside of the deep trench; creating a silicide within the deep trench in regions extending through the sidewall into an uncovered part of the substrate; removing the first conformal layer from the continuous spacer; removing the continuous spacer; depositing a layer of a high k dielectric material throughout the inside of the deep trench, and depositing a second conformal layer of a conductive material onto the layer of a high-k dielectric material.

Abstract: A method includes providing an SOI substrate including a layer of silicon disposed atop a layer of an oxide, the layer of an oxide being disposed atop the semiconductor substrate; forming a deep trench having a sidewall extending through the layer of silicon and the layer of an oxide and into the substrate; depositing a continuous spacer on the sidewall to cover the layer of silicon, the layer of an oxide and a part of the substrate; depositing a first conformal layer of a conductive material throughout the inside of the deep trench; creating a silicide within the deep trench in regions extending through the sidewall into an uncovered part of the substrate; removing the first conformal layer from the continuous spacer; removing the continuous spacer; depositing a layer of a high k dielectric material throughout the inside of the deep trench, and depositing a second conformal layer of a conductive material onto the layer of a high-k dielectric material.

Abstract: An electrical device is provided with a p-type semiconductor device having a first gate structure that includes a gate dielectric on top of a semiconductor substrate, a p-type work function metal layer, a metal layer composed of titanium and aluminum, and a metal fill composed of aluminum. An n-type semiconductor device is also present on the semiconductor substrate that includes a second gate structure that includes a gate dielectric, a metal layer composed of titanium and aluminum, and a metal fill composed of aluminum. An interlevel dielectric is present over the semiconductor substrate. The interlevel dielectric includes interconnects to the source and drain regions of the p-type and n-type semiconductor devices. The interconnects are composed of a metal layer composed of titanium and aluminum, and a metal fill composed of aluminum. The present disclosure also provides a method of forming the aforementioned structure.

Abstract: An electrical device is provided that in one embodiment includes a p-type semiconductor device having a first gate structure that includes a gate dielectric that is present on the semiconductor substrate, a p-type work function metal layer, a metal layer composed of titanium and aluminum, and a metal fill composed of aluminum. An n-type semiconductor device is also present on the semiconductor substrate that includes a second gate structure that includes a gate dielectric, a metal layer composed of titanium and aluminum, and a metal fill composed of aluminum. An interlevel dielectric is present over the semiconductor substrate. The interlevel dielectric includes interconnects to the source and drain regions of the p-type and n-type semiconductor devices. The interconnects are composed of a metal layer composed of titanium and aluminum, and a metal fill composed of aluminum. The present disclosure also provides a method of forming the aforementioned structure.

Abstract: A complementary metal oxide semiconductor (CMOS) structure including a scaled n-channel field effect transistor (nFET) and a scaled p-channel field transistor (pFET) which do not exhibit an increased threshold voltage and reduced mobility during operation is provided Such a structure is provided by forming a plasma nitrided, nFET threshold voltage adjusted high k gate dielectric layer portion within an nFET gate stack, and forming at least a pFET threshold voltage adjusted high k gate dielectric layer portion within a pFET gate stack. In some embodiments, the pFET threshold voltage adjusted high k gate dielectric layer portion in the pFET gate stack is also plasma nitrided.

Abstract: Replacement gate work function material stacks are provided, which provides a work function about the energy level of the conduction band of silicon. After removal of a disposable gate stack, a gate dielectric layer is formed in a gate cavity. A metallic compound layer including a metal and a non-metal element is deposited directly on the gate dielectric layer. At least one barrier layer and a conductive material layer is deposited and planarized to fill the gate cavity. The metallic compound layer includes a material having a work function about 4.4 eV or less, and can include a material selected from tantalum carbide and a hafnium-silicon alloy. Thus, the metallic compound layer can provide a work function that enhances the performance of an n-type field effect transistor employing a silicon channel.

Abstract: A method of simultaneously fabricating n-type and p type field effect transistors can include forming a first replacement gate having a first gate metal layer adjacent a gate dielectric layer in a first opening in a dielectric region overlying a first active semiconductor region. A second replacement gate including a second gate metal layer can be formed adjacent a gate dielectric layer in a second opening in a dielectric region overlying a second active semiconductor region. At least portions of the first and second gate metal layers can be stacked in a direction of their thicknesses and separated from each other by at least a barrier metal layer. The NFET resulting from the method can include the first active semiconductor region, the source/drain regions therein and the first replacement gate, and the PFET resulting from the method can include the second active semiconductor region, source/drain regions therein and the second replacement gate.

Abstract: The thickness and composition of a gate dielectric can be selected for different types of field effect transistors through a planar high dielectric constant material portion, which can be provided only for selected types of field effect transistors. Further, the work function of field effect transistors can be tuned independent of selection of the material stack for the gate dielectric. A stack of a barrier metal layer and a first-type work function metal layer is deposited on a gate dielectric layer within recessed gate cavities after removal of disposable gate material portions. After patterning the first-type work function metal layer, a second-type work function metal layer is deposited directly on the barrier metal layer in the regions of the second type field effect transistor. A conductive material fills the gate cavities, and a subsequent planarization process forms dual work function metal gate structures.

Abstract: Replacement gate stacks are provided, which increase the work function of the gate electrode of a p-type field effect transistor (PFET). In one embodiment, the work function metal stack includes a titanium-oxide-nitride layer located between a lower titanium nitride layer and an upper titanium nitride layer. The stack of the lower titanium nitride layer, the titanium-oxide-nitride layer, and the upper titanium nitride layer produces the unexpected result of increasing the work function of the work function metal stack significantly. In another embodiment, the work function metal stack includes an aluminum layer deposited at a temperature not greater than 420° C. The aluminum layer deposited at a temperature not greater than 420° C. produces the unexpected result of increasing the work function of the work function metal stack significantly.

Abstract: A structure and method for replacement metal gate (RMG) field effect transistors is disclosed. Silicide regions are formed on a raised source-drain (RSD) structure. The silicide regions form a chemical mechanical polish (CMP) stopping layer during a CMP process used to expose the gates prior to replacement. Protective layers are then applied and etched in the formation of metal contacts.

Abstract: A stack of a barrier metal layer and a first-type work function metal layer is deposited in replacement metal gate schemes. The barrier metal layer can be deposited directly on the gate dielectric layer. The first-type work function metal layer is patterned to be present only in regions of a first type field effect transistor. A second-type work function metal layer is deposited directly on the barrier metal layer in the regions of a second type field effect transistor. Alternately, the first-type work function layer can be deposited directly on the gate dielectric layer. The barrier metal layer is patterned to be present only in regions of a first type field effect transistor. A second-type work function metal layer is deposited directly on the gate dielectric layer in the regions of the second type field effect transistor. A conductive material fill and planarization form dual work function replacement gate structures.

Abstract: A method for forming a field effect transistor device includes forming an oxide layer on a substrate, forming a dielectric layer on the oxide layer, forming a first TiN layer on the dielectric layer, forming a metallic layer on the first layer, forming a second TiN layer on the metallic layer, removing a portion of the first TiN layer, the metallic layer, and the second TiN layer to expose a portion of the dielectric layer, forming a layer of stoichiometric TiN on the exposed portion of the dielectric layer and the second TiN layer, heating the device, and forming a polysilicon layer on the device.

Abstract: In one embodiment, the method for forming a complementary metal oxide semiconductor (CMOS) device includes providing a semiconductor substrate including a first device region and a second device region. An n-type conductivity semiconductor device is formed in one of the first device region or the second device region using a gate structure first process, in which the n-type conductivity semiconductor device includes a gate structure having an n-type work function metal layer. A p-type conductivity semiconductor device is formed in the other of the first device region or the second device region using a gate structure last process, in which the p-type conductivity semiconductor device includes a gate structure including a p-type work function metal layer.

Abstract: Adjustment of a switching threshold of a field effect transistor including a gate structure including a Hi-K gate dielectric and a metal gate is achieved and switching thresholds coordinated between NFETs and PFETs by providing fixed charge materials in a thin interfacial layer adjacent to the conduction channel of the transistor that is provided for adhesion of the Hi-K material, preferably hafnium oxide or HfSiON, depending on design, to semiconductor material rather than diffusing fixed charge material into the Hi-K material after it has been applied. The greater proximity of the fixed charge material to the conduction channel of the transistor increases the effectiveness of fixed charge material to adjust the threshold due to the work function of the metal gate, particularly where the same metal or alloy is used for both NFETs and PFETs in an integrated circuit; preventing the thresholds from being properly coordinated.