Abstract: A dual work function semiconductor device and method for fabricating the same are disclosed. In one aspect, a device includes a first and second transistor on a first and second substrate region. The first and second transistors include a first gate stack having a first work function and a second gate stack having a second work function respectively. The first and second gate stack each include a host dielectric, a gate electrode comprising a metal layer, and a second dielectric capping layer therebetween. The second gate stack further has a first dielectric capping layer between the host dielectric and metal layer. The metal layer is selected to determine the first work function. The first dielectric capping layer is selected to determine the second work function.

Abstract: A dual work function semiconductor device and method for fabricating the same are disclosed. In one aspect, a device includes a first and second transistor on a first and second substrate region. The first and second transistors include a first gate stack having a first work function and a second gate stack having a second work function respectively. The first and second gate stack each include a host dielectric, a gate electrode comprising a metal layer, and a second dielectric capping layer therebetween. The second gate stack further has a first dielectric capping layer between the host dielectric and metal layer. The metal layer is selected to determine the first work function. The first dielectric capping layer is selected to determine the second work function.

Abstract: A semiconductor device is disclosed that comprises a fully silicided electrode formed of an alloy of a semiconductor material and a metal, a workfunction modulating element for modulating a workfunction of the alloy, and a dielectric in contact with the fully silicided electrode. At least a part of the dielectric which is in direct contact with the fully silicided electrode comprises a stopping material for substantially preventing the workfunction modulating element from implantation into and/or diffusing towards the dielectric. A method for forming such a semiconductor device is also disclosed.

Abstract: One inventive aspect relates to a method of controlling the gate electrode in a silicidation process. The method comprises applying a sacrificial cap layer on top of each of at least one gate electrode, each of the at least one gate electrode deposited with a given height on a semiconductor substrate. The method further comprises applying an additional layer of oxide on top of the sacrificial layer. The method further comprises covering with a material the semiconductor substrate provided with the at least one gate electrode having the sacrificial cap layer with the additional oxide layer on top. The method further comprises performing a CMP planarization step. The method further comprises removing at least the material and the additional layer of oxide until on top of each of the at least one gate electrode the sacrificial cap layer is exposed.

Abstract: A dual work function semiconductor device and method for fabricating the same are disclosed. In one aspect, a device includes a first and second transistor on a first and second substrate region. The first and second transistors include a first gate stack having a first work function and a second gate stack having a second work function respectively. The first and second gate stack each include a host dielectric, a gate electrode comprising a metal layer, and a second dielectric capping layer therebetween. The second gate stack further has a first dielectric capping layer between the host dielectric and metal layer. The metal layer is selected to determine the first work function. The first dielectric capping layer is selected to determine the second work function.

Abstract: A method for manufacturing a MOSFET device with a fully silicided (FUSI) gate is described. This method may be used to prevent formation of shorts between the FUSI gate and a contact to a source and/or a drain region. In particular, the method discloses the formation of an expansion volume above a gate dielectric. The volume is designed to substantially contain the fully silicided gate.

Abstract: The present disclosure provides a dual workfunction semiconductor device and a method for manufacturing a dual workfunction semiconductor device. The method comprises providing a device on a first region and a device on a second region of a substrate. According to embodiments described herein, the method includes providing a dielectric layer onto the first and second region of the substrate, the dielectric layer on the first region being integrally deposited with the dielectric layer on the second region, and providing a gate electrode on top of the dielectric layer on both the first and second regions, the gate electrode on the first region being integrally deposited with the gate electrode on the second region.

Abstract: A semiconductor device is provided comprising a main electrode (4) and a dielectric (3) in contact with the main electrode (4), the main electrode (4) comprising a material having a work function and a work function modulating element (6) for modulating the work function of the material of the main electrode (4) towards a predetermined value. The main electrode (4) furthermore comprises a diffusion preventing dopant element (5) for preventing diffusion of the work function modulating element (6) towards and/or into the dielectric (3). Methods for forming such a semiconductor device are also described.

Abstract: A semiconductor device is disclosed that comprises a fully silicided electrode formed of an alloy of a semiconductor material and a metal, a workfunction modulating element for modulating a workfunction of the alloy, and a dielectric in contact with the fully silicided electrode. At least a part of the dielectric which is in direct contact with the fully silicided electrode comprises a stopping material for substantially preventing the workfunction modulating element from implantation into and/or diffusing towards the dielectric. A method for forming such a semiconductor device is also disclosed.

Abstract: One inventive aspect relates to a method of controlling the gate electrode in a silicidation process. The method comprises applying a sacrificial cap layer on top of each of at least one gate electrode, each of the at least one gate electrode deposited with a given height on a semiconductor substrate. The method further comprises applying an additional layer of oxide on top of the sacrificial layer. The method further comprises covering with a material the semiconductor substrate provided with the at least one gate electrode having the sacrificial cap layer with the additional oxide layer on top. The method further comprises performing a CMP planarization step. The method further comprises removing at least the material and the additional layer of oxide until on top of each of the at least one gate electrode the sacrificial cap layer is exposed.

Abstract: A method for manufacturing a MOSFET device with a fully silicided (FUSI) gate is described. This method may be used to prevent formation of shorts between the FUSI gate and a contact to a source and/or a drain region. In particular, the method discloses the formation of an expansion volume above a gate dielectric. The volume is designed to substantially contain the fully silicided gate.

Abstract: A method for manufacturing CMOS devices with fully silicided (FUSI) gates is described. A metallic gate electrode of an NMOS transistor and a metallic gate electrode of a pMOS transistor have a different work function. The work function of each transistor type is determined by selecting a thickness of a corresponding semiconductor gate electrode and a thermal budget of a first thermal step such that, during silicidation, different silicide phases are obtained on the nMOS and the pMOS transistors. The work function of each type of transistor can be adjusted by selectively doping the semiconductor material prior to the formation of the silicide.