Abstract: The present disclosure provides a semiconductor device that includes a semiconductor substrate having a first region and a second region, a pMOS transistor formed over the first region and an nMOS formed over the second region. The pMOS transistor has a gate structure that includes: an interfacial layer formed over the substrate; a AlOx layer formed over the interfacial layer; and a metal layer including Mo or W formed over the AlOx layer. The nMOS transistor has a gate structure that includes: the interfacial layer formed over the substrate; a DyOx layer formed over the interfacial layer; and the metal layer including Mo or W formed over the DyOx layer.

Abstract: A field effect transistor having a gate structure comprising a high-K dielectric layer, a gate electrode located on the high-K dielectric layer, and an interfacial layer located in between the high-K dielectric layer and a channel region of the field effect transistor. The interfacial layer comprises a layer of SiO2 containing a regrowth inhibiting agent. A method of forming the gate structure includes forming a gate stack comprising, in order: a SiO2 layer adjacent a channel region of the field effect transistor; a high-K dielectric layer on the SiO2 layer; and a gate electrode on the high-K dielectric layer. The method also includes introducing a regrowth inhibiting agent into the SiO2 layer and then annealing the gate structure. The presence of the regrowth inhibiting agent in the SiO2 interfacial layer inhibits regrowth of the SiO2 layer into the channel region during the annealing step.

Abstract: A field effect transistor having a gate structure that comprises an interfacial layer positioned in between the transistor channel region and a high-K dielectric layer of the gate stack. The interfacial layer comprises AlxSiyOz, which has a higher relative dielectric constant value than SiO2. A method of forming the gate structure of a field effect transistor. The method includes forming a gate stack comprising, in order: a SiO2-based layer adjacent a channel region of the field effect transistor; a high-K dielectric layer on the SiO2-based layer; and a gate electrode on the high-K dielectric layer. The method also includes introducing Al into the SiO2-based layer to form an AlxSiyOz interfacial layer in between the high-K dielectric layer and the channel region. A heating step to allows Al introduced into channel region to diffuse out of the channel region into the interfacial layer.

Abstract: A field effect transistor having a gate structure comprising a high-K dielectric layer, a gate electrode located on the high-K dielectric layer, and an interfacial layer located in between the high-K dielectric layer and a channel region of the field effect transistor. The interfacial layer comprises a layer of SiO2 containing a regrowth inhibiting agent. A method of forming the gate structure includes forming a gate stack comprising, in order: a SiO2 layer adjacent a channel region of the field effect transistor; a high-K dielectric layer on the SiO2 layer; and a gate electrode on the high-K dielectric layer. The method also includes introducing a regrowth inhibiting agent into the SiO2 layer and then annealing the gate structure. The presence of the regrowth inhibiting agent in the SiO2 interfacial layer inhibits regrowth of the SiO2 layer into the channel region during the annealing step.

Abstract: The present disclosure provides a semiconductor device that includes a semiconductor substrate having a first region and a second region, a pMOS transistor formed over the first region and an nMOS formed over the second region. The pMOS transistor has a gate structure that includes: an interfacial layer formed over the substrate; a AlOx layer formed over the interfacial layer; and a metal layer including Mo or W formed over the AlOx layer. The nMOS transistor has a gate structure that includes: the interfacial layer formed over the substrate; a DyOx layer formed over the interfacial layer; and the metal layer including Mo or W formed over the DyOx layer.

Abstract: A field effect transistor having a gate structure that comprises an interfacial layer positioned in between the transistor channel region and a high-K dielectric layer of the gate stack. The interfacial layer comprises AlxSiyOz, which has a higher relative dielectric constant value than SiO2. A method of forming the gate structure of a field effect transistor. The method includes forming a gate stack comprising, in order: a SiO2-based layer adjacent a channel region of the field effect transistor; a high-K dielectric layer on the SiO2-based layer; and a gate electrode on the high-K dielectric layer. The method also includes introducing Al into the SiO2-based layer to form an AlxSiyOz interfacial layer in between the high-K dielectric layer and the channel region. A heating step to allows Al introduced into channel region to diffuse out of the channel region into the interfacial layer.