Abstract: Various embodiments provide electrostatic discharge protection structures and methods for forming the same. An exemplary structure can include a semiconductor chip including a through hole. The structure can further include a through silicon via (TSV) structure disposed within the through hole and passing through the semiconductor chip. The TSV structure can have a first surface and a second surface. The structure can further include a tunneling dielectric layer disposed on the first surface of the TSV structure. The tunneling dielectric layer can have a surface area covering a top view surface area of the TSV structure and a surface portion of the semiconductor chip surrounding the TSV structure. Yet further, the structure can include a metal material discretely dispersed in the tunneling dielectric layer, a first electrode disposed on the tunneling dielectric layer, and a second electrode disposed on the second surface of the TSV structure.

Abstract: A semiconductor device and its fabrication method are provided. A first dielectric layer is provided to cover a substrate. The first dielectric layer contains a plurality of first conductive layers. A portion of each first conductive layer is removed to form a plurality of first openings in the first dielectric layer. A second dielectric layer is formed in each first opening. A third dielectric layer having second-openings are formed on the first dielectric layer and on the second dielectric layers. Each second-opening exposes at least two adjacent second dielectric layers. Second dielectric layers exposed by a first second-opening are removed to form third openings to expose corresponding first conductive layers. Second conductive layers are formed in the third opening and the second-openings including the first second-opening. Stable electrical interconnections with high quality electrical isolations can be provided.

Abstract: An enhanced optical proximity correction method is provided. The method includes providing a mask substrate and a substrate and obtaining a customer target pattern. The method also includes obtaining a production layout by performing an optical proximity correction process onto the customer target pattern using the pattern and a pattern formed on the substrate. Further, the method includes obtaining the light intensity information instead of dimension of the production layout. Further, the method includes storing the light intensity information of the production layout, the production layout and surrounding coherence radius in an optical proximity correction model database if the light intensity information of the production layout does not coincide with light intensity information of original modeling patterns already stored in the optical proximity correction model database.

Abstract: A method is provided for fabricating a semiconductor structure. The method includes providing a to-be-etched layer; and forming a hard mask layer on the to-be-etched layer. The method also includes forming a photoresist layer on the hard mask layer; and forming a patterned photoresist layer having openings exposing the hard mask layer by exposing and developing the photoresist layer. Further, the method includes forming sidewall spacers on side surfaces of the openings; and forming a patterned hard mask layer by etching the hard mask layer using the patterned photoresist layer and the sidewall spacers as an etching mask such that patterns in the hard mask layer have a substantially right angle at edge. Further, the method also includes forming to-be-etched patterns by etching the to-be-etched layer based on the patterned hard mask layer.

Abstract: Various embodiments provide semiconductor structures and methods for forming the same. In an exemplary method, a substrate can be provided. The substrate can have a plurality of isolation structures. A top surface of the plurality of isolation structures can be higher than a surface of the substrate. A device layer can be formed on the substrate and on the plurality of isolation structures. The device layer can be polished using a polishing process, such that the top surface of the plurality of isolation structures are exposed, with residue remaining on the device layer and on the plurality of isolation structures. The residue can be removed from the device layer and from the plurality of isolation structures using a non-polishing-removal process, such that the top surface of the plurality of isolation structures and a top surface of the device layer are substantially leveled and smooth.

Abstract: Various embodiments provide multi-gate VDMOS transistors. The transistor can include a substrate having a first surface and a second surface opposite to the first surface, a drift layer on the first surface of the substrate, and an epitaxial layer on the drift layer. The transistor can further include a plurality of trenches. Each trench can pass through the epitaxial layer and a thickness portion of the drift layer. The transistor can further include a plurality of gate structures. Each gate structure can fill the each trench. The transistor can further include a plurality of doped regions in the epitaxial layer. Each doped region can surround a sidewall of the each gate structure. The transistor can further include a source metal layer on the epitaxial layer to electrically connecting the plurality of doped regions, and a drain metal layer on the second surface of the substrate.

Abstract: A method for repairing defective memory cells includes receiving an access command having an access address and an access operation. The access address includes a row address and a column address. The method further includes determining whether the row address and the column address are the same as a pre-recorded row address and column address of a defective memory cell. If the row and column addresses of the access address are the same as the respective row and column addresses of the defective memory cell, the method includes replacing the defective memory cell with a redundant memory cell, and executing the access operation using the redundant memory cell.

Abstract: A semiconductor apparatus and a manufacturing method therefor is described. The semiconductor apparatus comprises a substrate and a gate structure for a N-channel semiconductor device above the substrate. A recess is formed at a lower end portion of at least one of two sides of the gate where it is adjacent to a source region and a drain region, of the N-channel semiconductor. The channel region of the N-channel semiconductor device has enhanced strain. The apparatus can further have a gate structure for a P-channel semiconductor device above the substrate.

Abstract: Local interconnect structures and fabrication methods are provided. A dielectric layer can be formed on a semiconductor substrate. A first film layer can be patterned on the dielectric layer to define a region surrounded by a local interconnect structure to be formed. A sidewall spacer can be formed and patterned surrounding the first film layer on an exposed surface portion of the dielectric layer. A second film layer can be formed on the exposed surface portion of the dielectric layer and can have a top surface substantially flushed with a top surface of the sidewall spacer. The patterned sidewall spacer can be removed to form a first opening. After forming the first opening, the dielectric layer can be etched to form a second opening through the dielectric layer. The second opening can be filled with a conductive material to form the local interconnect structure.

Abstract: Various embodiments provide LDMOS devices and fabrication methods. An N-type buried isolation region is provided in a P-type substrate. A P-type epitaxial layer including a first region and a second region is formed over the P-type substrate. The first region is positioned above the N-type buried isolation region, and the second region surrounds the first region. An annular groove is formed in the second region to surround the first region and to expose a surface of the N-type buried isolation region. Isolation layers are formed on both sidewalls of the annular groove. An annular conductive plug is formed in the annular groove between the isolation layers. The annular conductive plug is in contact with the N-type buried isolation region at the bottom of the annular conductive plug. A gate structure of an LDMOS transistor is formed over the first region of the P-type epitaxial layer.

Abstract: An electrostatic discharge (ESD) protection structure and an ESD protection circuit are provided. A PMOS transistor is located in a first region of a first N-type well region of a semiconductor substrate. A first doped base region located in a second region of a first N-type well region is N-type doped and connected to an external trigger-voltage adjustment circuit. An NMOS transistor is located in a third region of a first P-type well region. A second doped base region located in the fourth region of the first P-type well region is P-type doped and connected to the external trigger-voltage adjustment circuit. The external trigger-voltage adjustment circuit can be configured to pull up an electric potential of the second doped base region when the power supply terminal generates an instantaneous electric potential difference.

Abstract: A method may be implemented for obtaining calibration data for use in calibrating an optical proximity correction model. The method may include capturing an image for each portion of a plurality of portions of a wafer to obtain captured images. The method may further include assembling at least portions of the captured images to form an assembled image. The method may further include mapping layout data of the wafer with the assembled image. The method may further include selecting portions of the assembled image based on the layout data of the wafer. The method may further include obtaining data associated with the portions of the assembled image as the calibration data.

Abstract: A semiconductor device and method of forming the same includes a substrate having a NMOS region and a PMOS region. The method includes forming a dummy gate structure having a stacked sacrificial dielectric layer and a sacrificial gate material layer on the NMOS and PMOS regions. The method further includes concurrently removing the stacked sacrificial dielectric layer and a sacrificial gate material layer to form a groove, and forming a high-K dielectric layer and a first metal gate layer in the grove. The method also includes forming a hard mask over the NMOS region, removing the first metal gate layer and the high-K dielectric layer in the PMOS region to form a channel groove, forming a second high-K dielectric layer and a second metal gate layer in the channel grove, and removing the hard mask. The work function metal layer in the NMOS and PMOS regions can be independently controlled.

Abstract: Semiconductor devices and fabrication methods are provided. A semiconductor substrate includes a first region and a second region. A gate dielectric material layer is formed to cover the first region, and a control gate dielectric layer is formed over a surface portion of the second region. The control gate dielectric layer has a top surface higher than the gate dielectric layer. A gate material layer is conformally formed to cover an entire surface of the semiconductor substrate and has a top surface in the second region higher than a top surface in the first region. A first filling material layer is formed on the gate material layer. A first patterned mask layer is formed on the first filling material layer to form a gate on a gate dielectric layer in the first region. A control gate is formed on the control gate dielectric layer of the second region.

Abstract: A method is provided for fabricating a nano field-effect vacuum tube. The method includes providing a substrate having an insulating layer and a sacrificial layer; and forming a sacrificial line, a source sacrificial layer and a drain sacrificial layer. The method also includes forming a trench in the insulating layer; and forming a dielectric layer on the surface of the sacrificial line. Further, the method includes forming a metal layer on the dielectric layer to fill up the trench, cover the sacrificial line and expose the source sacrificial layer and the drain sacrificial layer; and removing the source sacrificial layer and the drain sacrificial layer. Further, the method also includes removing the sacrificial line to form a through channel; forming an isolation layer on the metal layer; and forming a source region and a drain region on the insulating layer at both ends of the metal layer.

Abstract: Semiconductor devices including porous low-k dielectric layers and fabrication methods are provided. A dielectric layer is formed on a substrate by introducing and polymerizing a main reaction gas on a surface of the substrate. The main reaction gas has a chemical structure including a ring-shaped group, silicon, carbon, and hydrogen, and the ring-shaped group includes at least carbon and hydrogen. A porous low-k dielectric layer is then formed from the dielectric layer by curing the dielectric layer with UV light.

Abstract: Three dimensional quantum well transistors and fabrication methods are provided. A quantum well layer, a barrier layer, and a gate structure can be sequentially formed on an insulating surface of a fin part. The gate structure can be formed over the barrier layer and across the fin part. The QW layer and the barrier layer can form a hetero-junction of the transistor. A recess can be formed in the fin part on both sides of the gate structure to suspend a sidewall spacer. A source and a drain can be formed by growing an epitaxial material in the recess and the sidewall spacer formed on both sidewalls of the gate electrode can be positioned on surface of the source and the drain.

Abstract: A semiconductor device containing an MIM capacitor and its fabrication method are provided. A metal-insulator-metal (MIM) capacitor is formed on a first interlayer dielectric layer covering a substrate. The MIM capacitor includes a bottom electrode layer and a top electrode layer that are isolated from and laterally staggered with one another. A second interlayer dielectric layer is formed to cover both the MIM capacitor and the first interlayer dielectric layer. A first conductive plug and a second conductive plug are formed each passing through the second interlayer dielectric layer. The first conductive plug contacts a sidewall and a surface portion of the top electrode layer of the MIM capacitor and the second conductive plug contacts a sidewall and a surface portion of the bottom electrode layer of the MIM capacitor.

Abstract: Various embodiments provide shallow trenches and fabrication methods. In an exemplary method, a semiconductor substrate can be provided. A mask layer can be provided on the semiconductor substrate. An etch-cleaning process can be performed. The etch-cleaning process can include etching the semiconductor substrate to form a shallow trench by one or more etching steps using the mask layer as an etch mask. The etch-cleaning process can further include performing a plasma cleaning process after each of the one or more etching steps. The plasma cleaning process can use a plasma that is electronegative.

Abstract: A semiconductor device includes a substrate, a first barrier layer disposed on the substrate, a first dielectric layer disposed on the first barrier layer, and a second barrier layer disposed on the first barrier layer. The semiconductor device further includes a third barrier layer and a first metal gate each being disposed between a first portion of the second barrier layer and a second portion of the second barrier layer. The first metal gate is disposed between the third barrier layer and the substrate. The semiconductor device further includes a second dielectric layer. The third barrier layer is disposed between the first metal gate and the second dielectric layer. The semiconductor device further includes a second metal gate. The semiconductor device further includes a contact hole positioned between the first metal gate and the second metal gate.