Abstract: A method for fabricating a semiconductor device is described. A substrate having thereon a polysilicon resistor is provided. A dielectric layer is formed over the substrate covering the polysilicon resistor. The dielectric layer is etched to form a contact opening over the polysilicon resistor, with overetching into the polysilicon resistor. A metal silicide layer is formed on the polysilicon resistor in the contact opening. A metal material is filled in the contact opening. A portion of the dielectric layer, the metal material, and a portion of the polysilicon resistor are removed to expose the metal silicide layer. A metal contact is formed over the metal silicide layer.

Abstract: A mark structure for measuring the alignment accuracy between a former layer and a latter layer with electron beam inspection (EBI) is described. The mark structure includes multiple divisions, each of which includes at least one region that includes multiple parts each disposed with a pair of a pattern of the former layer and a pattern of the latter layer. In each region, all of the parts have the same distance in a direction between the pattern of the former layer and the pattern of the latter layer. The distance in the direction is varied over the regions of the divisions of the mark structure.

Abstract: A method for fabricating a semiconductor device is described. A substrate having thereon a polysilicon resistor is provided. A dielectric layer is formed over the substrate covering the polysilicon resistor. The dielectric layer is etched to form a contact opening over the polysilicon resistor, with overetching into the polysilicon resistor. A metal silicide layer is formed on the polysilicon resistor in the contact opening. A metal material is filled in the contact opening. A portion of the dielectric layer, the metal material, and a portion of the polysilicon resistor are removed to expose the metal silicide layer. A metal contact is formed over the metal silicide layer.

Abstract: A thin film resistor structure includes a substrate, a flat bottom ILD (inter layer dielectric) disposed on the substrate, a plurality of first contacts disposed in the bottom ILD, and each top surface of the first contacts is on the same level as a top surface of the bottom ILD; a flat top ILD disposed on the bottom ILD, a plurality of second contacts disposed in the top ILD, and each top surface of the second contacts is on the same level as a top surface of the top ILD, and a thin film resistor disposed between the bottom ILD and the top ILD.

Abstract: A semiconductor structure includes a gate structure disposed on a substrate and having an outer spacer, a recess disposed in the substrate and adjacent to the gate structure, a doped epitaxial material filling up the recess, a cap layer including an undoped epitaxial material and disposed on the doped epitaxial material, a lightly doped drain disposed below the cap layer and sandwiched between the doped epitaxial material and the cap layer, and a silicide disposed on the cap layer and covering the doped epitaxial material to cover the cap layer together with the outer spacer without directly contacting the lightly doped drain.

Abstract: An opening structure is disclosed. The opening structure includes: a semiconductor substrate; at least one dielectric layer disposed on the semiconductor substrate, wherein the dielectric layer has a plurality of openings exposing the semiconductor substrate, and each of the openings has a sidewall; a dielectric thin film covering at least a portion of the sidewall of each of the openings; an etch stop layer disposed between the semiconductor substrate and the dielectric layer and extending partially into the openings to isolate the dielectric thin film from the semiconductor substrate; and a metal layer filled in the openings.

Abstract: The present invention relates to a fabricating method of a semiconductor element. First, a substrate is provided and a first layout structure having a first width is formed on the substrate. Then, an etching mask is formed to cover the first layout structure, and the etching mask exposes a portion of the first layout structure. After that, the first layout structure is etched with the etching mask to form a second layout structure having a second width. The second width is less than the first width. This fabricating method is capable of finishing the fabrication of gate structures in two different directions. Accordingly, the layout flexibility is improved.

Abstract: A method of fabricating openings is disclosed. First, a semiconductor substrate having a salicide region thereon is provided. An etch stop layer and at least a dielectric layer are disposed on the semiconductor substrate from bottom to top. Second, the dielectric layer and the etching stop layer are patterned to form a plurality of openings in the dielectric layer and in the etching stop layer so that the openings expose the salicide region. Then, a dielectric thin film covering the dielectric layer, sidewalls of the openings and the salicide region is formed. Later, the dielectric thin film disposed on the dielectric layer and on the salicide region is removed.

Abstract: A mark structure for measuring the alignment accuracy between a former layer and a latter layer with electron beam inspection (EBI) is described. The mark structure includes multiple divisions, each of which includes at least one region that includes multiple parts each disposed with a pair of a pattern of the former layer and a pattern of the latter layer. In each region, all of the parts have the same distance in a direction between the pattern of the former layer and the pattern of the latter layer. The distance in the direction is varied over the regions of the divisions of the mark structure.

Abstract: A semiconductor substrate having an etch stop layer and at least a dielectric layer disposed from bottom to top is provided. The dielectric layer and the etching stop layer is then patterned to form a plurality of openings exposing the semiconductor substrate. A dielectric thin film is subsequently formed to cover the dielectric layer, the sidewalls of the openings, and the semiconductor substrate. The dielectric thin film disposed on the dielectric layer and the semiconductor substrate is then removed while the dielectric thin film disposed on the sidewalls remains.

Abstract: An opening structure includes a semiconductor substrate, at least one dielectric layer disposed on the semiconductor substrate, wherein the dielectric layer has a plurality of openings exposing the semiconductor substrate, and each of the openings has a sidewall, a dielectric thin film covering at least a portion of the sidewall of each of the openings, and a metal layer filled in the openings.

Abstract: A method of fabricating a self-aligned contact is provided. A first dielectric layer is formed on a substrate having a contact region therein. Next, a lower hole corresponding to the contact region is formed in the first dielectric layer. Thereafter, a second dielectric layer is formed on the first dielectric layer, and then an upper hole self-aligned to and communicated with the lower hole is formed in the second dielectric layer, wherein the upper hole and the lower hole constitute a self-aligned contact hole. Afterwards, the self-aligned contact hole is filled with a conductive layer.

Abstract: A method for fabricating a metal-oxide semiconductor (MOS) transistor is disclosed. The method includes the steps of: providing a semiconductor substrate; forming a silicon layer on the semiconductor substrate; performing a first photo-etching process on the silicon layer for forming a gate pattern; forming an epitaxial layer in the semiconductor substrate adjacent to two sides of the gate pattern; and performing a second photo-etching process on the gate pattern to form a slot in the gate pattern while using the gate pattern to physically separate the gate pattern into two gates.

Abstract: An opening structure is disclosed. The opening structure includes: a semiconductor substrate; at least one dielectric layer disposed on the semiconductor substrate, wherein the dielectric layer has a plurality of openings exposing the semiconductor substrate, and each of the openings has a sidewall; a dielectric thin film covering at least a portion of the sidewall of each of the openings; an etch stop layer disposed between the semiconductor substrate and the dielectric layer and extending partially into the openings to isolate the dielectric thin film from the semiconductor substrate; and a metal layer filled in the openings.

Abstract: A structure of a memory cell of a static random memory device and a process for fabricating the same are disclosed. The memory cell includes a substrate having an active region including an N-well and a shallow trench isolation structure; a first gate and a second gate formed over the substrate; a halo region, a LLD, and a source and drain region formed on two sides of the first gate; an interlevel dielectric layer covering the substrate, the first and second gates; and a contact penetrating the interlevel dielectric layer and extending to the source and drain region, no halo region is formed under the contact.

Abstract: An opening structure includes a semiconductor substrate, at least one dielectric layer disposed on the semiconductor substrate, wherein the dielectric layer has a plurality of openings exposing the semiconductor substrate, and each of the openings has a sidewall, a dielectric thin film covering at least a portion of the sidewall of each of the openings, and a metal layer filled in the openings.

Abstract: An alignment mark for defect inspection is disclosed. The alignment mark includes: a semiconductor substrate; a first type well disposed in the semiconductor substrate; a second type doping region disposed in the first type well; a dielectric layer disposed on the semiconductor substrate to cover the first type well and the second type doping region; and a plurality of conductive plugs formed in the dielectric layer for connecting to the second type doping region.

Abstract: The method for in-line monitoring a wafer is described as follows. A wafer is provided, and at least one inspection structure is then formed on the wafer in the following steps. An N-well region and a P-well region are formed in the wafer, wherein the N-well region and the P-well region are separated from each other. A gate on each of the N-well region and the P-well region is formed. A P-type doped region is respectively formed in the N-well region and in the P-well region at both sides of the gates. A first contact plug is formed on each P-type doped region, and second contact plug is formed on each gate. Afterwards, a defect inspection is conducted utilizing an electron beam inspection (EBI) system, such that a short between each first contact plug and each gate is determined.

Abstract: A substrate having an etch stop layer and at least a dielectric layer disposed from bottom to top is provided. The dielectric layer is then patterned to form a plurality of openings exposing the etch stop layer. A dielectric thin film is subsequently formed to cover the dielectric layer, the sidewalls of the openings, and the etch stop layer. The dielectric thin film disposed on the dielectric layer and the etch stop layer is then removed.

Abstract: A defect inspection method is disclosed. A first type defect inspection system is used to perform a first defect inspection by aligning to an alignment mark on a wafer as a reference point for the first defect inspection. A fabrication process is performed on the wafer thereafter, and a second defect inspection is performed by using a second type defect inspection system to align the alignment mark on the wafer as the reference point for the second defect inspection.