Abstract: The present disclosure provides an LDMOS device and a manufacturing method thereof.

Abstract: The present disclosure provides an LDMOS device and a manufacturing method thereof.

Abstract: The present disclosure provides an LDMOS device and a manufacturing method thereof.

Abstract: A method is provided for fabricating a buried-channel MOSFET and a surface-channel MOSFET of the same type and different gate electrodes on a same wafer. The method includes providing a semiconductor substrate having a well area and a plurality of shallow trench isolation structures; forming a threshold implantation region doped with impurity ions opposite of that of the well area in the well area for the buried-channel MOSFET; forming a gate structure including a gate dielectric layer and a gate electrode on the semiconductor substrate, wherein the gate electrode of the buried-channel MOSFET is doped with impurity ions with a same type as that of the well area, and the gate electrode of the surface-channel MOSFET is doped with impurity ions with a type opposite of that of the well area; and forming source and drain regions in the semiconductor substrate at both sides of the gate structure.

Abstract: A method is provided for fabricating a buried-channel MOSFET and a surface-channel MOSFET of the same type and different gate electrodes on a same wafer. The method includes providing a semiconductor substrate having a well area and a plurality of shallow trench isolation structures; forming a threshold implantation region doped with impurity ions opposite of that of the well area in the well area for the buried-channel MOSFET; forming a gate structure including a gate dielectric layer and a gate electrode on the semiconductor substrate, wherein the gate electrode of the buried-channel MOSFET is doped with impurity ions with a same type as that of the well area, and the gate electrode of the surface-channel MOSFET is doped with impurity ions with a type opposite of that of the well area; and forming source and drain regions in the semiconductor substrate at both sides of the gate structure.

Abstract: The current invention teaches the use of e-beam patterning techniques for forming contact and via holes of diameter less than about 0.15 microns down to 0.05 microns. E-beam lithography has higher resolution (down to 30-50 nanometers) as compared to 130-150 nanometer when using deep ultra violet (DUV) photolithography patterning techniques. In addition the invention uses a mix and match approach by employing a conventional I-line, or deep UV, resist to form the trench pattern and e-beam lithography tools to form the contact and vial hole patterns. A simplified process scheme is developed where contact/via holes are formed first on solvent developable e-beam resist and the trench pattern is formed on aqueous developable photoresist coated on top of the e-beam resist.

Abstract: Under the first embodiment of the invention, a three layer composite layer of insulation is deposited. The trench is etched into this composite layer of insulation followed by a hard bake. The via etch is performed, completing the formation of the dual damascene profile. The created dual damascene profile is transferred into the underlying substrate; the layer of photoresist is removed. Under the second embodiment of the invention, a two layer composite layer of insulation is deposited over a semiconductor surface. The trench is etched into this composite layer of insulation. A layer of positive photoresist is deposited over the second layer of cross-linked negative resist and masked for the via etch. The via etch is performed, the created dual damascene profile is transferred into the underlying substrate. The removal of the layers of patterned photoresist completes the formation of the dual damascene structure.