A control gate electrode and a memory gate electrode of a memory cell of a non-volatile memory are formed in a memory cell region of a semiconductor substrate, and a dummy gate electrode is formed in a peripheral circuit region. Then, n.sup.+-type semiconductor regions for a source or a drain of the memory cell are formed in the memory cell region and n.sup.+-type semiconductor regions for a source or a drain of MISFET are formed in the peripheral circuit region. Then, a metal silicide layer is formed over the n.sup.+-type semiconductor regions but the metal silicide layer is not formed over the control gate electrode, the memory gate electrode, and the gate electrode. Subsequently, the gate electrode is removed and replaced with the gate electrode for MISFET, Then, after removing the gate electrode and replacing it with a gate electrode for MISFET, a metal silicide layer is formed over the memory gate electrode and the control gate electrode.

A method for manufacturing a semiconductor device to provide a Metal Insulator Semiconductor Field Effect Transistor (MISFET) in a first region of a semiconductor substrate includes forming a first gate insulating film on the semiconductor substrate in the first region, forming a first gate electrode containing silicon on the first gate insulating film, forming first impurity regions inside the semiconductor substrate so as to sandwich the first gate electrode in the first region, the first impurity regions configuring a part of a first source region and a part of a first drain region, forming a first silicide layer on the first impurity region, forming a first insulating film on the semiconductor substrate so as to cover the first gate electrode and the first silicide layer, polishing the first insulating film so as to expose the first gate electrode, and forming a second silicide layer on the first gate electrode.

A self-aligning preparation method for a drain underlap region in a tunnel field effect transistor: designing asymmetric side wall structures on two sides of the gate of a tunnel field effect transistor, the side of the gate closest to the source region being a thin side wall and the side of the gate closest to the drain region being a thick side wall; and using the source region thin side wall as a hard mask for implantation of the source region of the transistor and the drain region thick side wall as a hard mask for implantation of the drain region of the transistor. The present method effectively uses the thin side walls and thick side walls existing in standard CMOS processes to suppress the ambipolar effect of the tunnel field effect transistor without introducing special materials and special processes, and also optimizes the device variation characteristics. The present method ensures that the tunnel field effect transistor can be monolithically integrated with standard CMOS devices to implement more complex and diverse circuit functions.

The present invention relates to an aqueous chemical composition C for removing from a substrate selectively under heat residues of a nickel-platinum alloy containing at least 8% by weight of Pt compared to the total weight of nickel-platinum alloy, characterised in that it is prepared by mixing a composition B comprising bromide ions and a composition H comprising hydrogen peroxide such that in the composition C, at the moment of mixing, the molar concentration of bromide ions is comprised between 0.15 mol/L and 0.45 mol/L and the molar ratio of hydrogen peroxide with respect to bromide ions is comprised between 1.1 and 2.

The invention also pertains to a method for selectively removing nickel-platinum alloy residues containing at least 8% by weight of Pt compared to the total weight of nickel-platinum alloy from a substrate, comprising the following steps: preparing under heat a chemical composition C according to any one of claims 1 to 3, placing the hot chemical composition C and the substrate in contact for a sufficient duration to remove the nickel-platinum alloy residues from the substrate.

A semiconductor structure includes one or more channel layers; a gate structure engaging the one or more channel layers; a first source/drain feature connected to a first side of the one or more channel layers and adjacent to the gate structure; a first dielectric cap disposed over the first source/drain feature, wherein a bottom surface of the first dielectric cap is below a top surface of the gate structure; a first via disposed under and electrically connected to the first source/drain feature; and a power rail disposed under and electrically connected to the first via.

A control gate electrode and a memory gate electrode of a memory cell of a non-volatile memory are formed in a memory cell region of a semiconductor substrate, and a dummy gate electrode is formed in a peripheral circuit region. Then, n.sup.+-type semiconductor regions for a source or a drain of the memory cell are formed in the memory cell region and n.sup.+-type semiconductor regions for a source or a drain of MISFET are formed in the peripheral circuit region. Then, a metal silicide layer is formed over the n.sup.+-type semiconductor regions but the metal silicide layer is not formed over the control gate electrode, the memory gate electrode, and the gate electrode. Subsequently, the gate electrode is removed and replaced with the gate electrode for MISFET. Then, after removing the gate electrode and replacing it with a gate electrode for MISFET, a metal silicide layer is formed over the memory gate electrode and the control gate electrode.

Integrated circuits including LDMOS transistor structures and methods for fabricating LDMOS transistor structures are provided. An exemplary method for fabricating an LDMOS transistor structure includes providing a semiconductor-on-insulator (SOI) substrate including a semiconductor layer overlying an insulator layer overlying a bulk layer. The method includes forming a gate structure overlying the substrate. A channel region is formed in the semiconductor layer under the gate structure. The method includes forming a source region overlying the substrate. Further, the method includes forming a drain region overlying the substrate. A drift region is located between the drain region and the gate structure. Also, the method includes forming contacts to the gate structure, the source region, and the drain region.

A semiconductor device has a silicide source/drain region is fabricated by growing silicon on an epitaxial region including silicon and either germanium or carbon. In the method, a gate electrode is formed on a semiconductor substrate with a gate insulating layer interposed therebetween. An epitaxial layer is formed in the semiconductor substrate at both sides of the gate electrodes. A silicon layer is formed to cap the epitaxial layer. The silicon layer and a metal material are reacted to form a silicide layer. In a PMOS, the epitaxial layer has a top surface and inclined side surfaces that are exposed above the upper surface of the active region. The silicon layer is grown on the epitaxial layer in such a way as to cap the top and inclined surfaces.

An MISFET has a gate electrode formed on a semiconductor substrate via a gate insulating film, and a source region and a drain region formed inside the semiconductor substrate so as to sandwich the gate electrode. And, a first silicide layer is formed on surfaces of the source region and the drain region, and a second silicide layer is formed on a surface of the gate electrode. Each of the first silicide layer and the second silicide layer is made of a first metal and silicon, and further contains a second metal different from the first metal. And, a concentration of the second metal inside the second silicide layer is lower than a concentration of the second metal inside the first silicide layer.

Structures for a transistor and methods of forming a structure for a transistor. The structure includes a first dielectric spacer, a second dielectric spacer, and a gate laterally between the first dielectric spacer and the second dielectric spacer. The gate includes a first silicide layer extending from the first dielectric spacer to the second dielectric spacer. The structure further includes a second silicide layer within the first silicide layer, and a contact that is aligned to the second silicide layer.