Abstract: A method of forming an etch mask includes: providing a substrate having thereon a material layer to be etched; forming a hard mask layer consisting of a radiation-sensitive, single-layer resist material on the material layer; exposing the hard mask layer to actinic energy to change solvent solubility of exposed regions of the hard mask layer; and subjecting the hard mask layer to water treatment to remove the exposed regions of the hard mask layer, thereby forming a masking pattern consisting of unexposed regions of the hard mask layer.

Abstract: A post-CMP wafer cleaning apparatus includes a chamber; a plurality of rollers adapted to hold and rotate a wafer within the chamber; at least one brush adapted to scrub a surface of the wafer to be cleaned; and a liquid spraying device adapted to spray a liquid on the wafer, the liquid spraying device comprising two spray bars jointed together via a joint member.

Abstract: A method for manufacturing a buried-strap includes: forming a trench capacitor structure in a semiconductor substrate, wherein the trench capacitor structure has a doped polysilicon layer and an isolation collar covered by the doped polysilicon layer, and a top surface of the doped polysilicon layer is lower than a top surface of the semiconductor substrate such that a first recess is formed; sequentially forming a first resist layer, a second resist layer and a third resist layer over the semiconductor substrate; sequentially patterning the third resist layer, the second resist layer and the first resist layer, forming a patterned tri-layer resist layer over the semiconductor substrate; partially removing a portion of the doped polysilicon layer exposed by the patterned tri-layer resist layer to form a second recess; removing the patterned tri-layer resist layer; and forming an insulating layer in the second recess and a portion of the first recess.

Abstract: A vertical MOSFET electrostatic discharge device is disclosed, including a substrate comprising a plurality of trenches, a recessed gate disposed in each trench, a drain region disposed between each of the two neighboring recessed gates, an electrostatic discharge implant region disposed under each drain region, and a source region surrounding and disposed under the recessed gates and the electrostatic discharge implant regions.

Abstract: A method for fabricating a gate dielectric layer comprises the steps of: forming a dielectric layer on a semiconductor substrate; performing a nitrogen treating process to form a nitride layer on the dielectric layer; and performing a thermal treating process at 1150-1400° C. for a period of 400-800 milliseconds, to form a gate dielectric layer. A step of forming a gate layer on the gate dielectric layer may be performed to form a gate structure.

Abstract: The present invention relates to a plasma etching method and apparatus for preparing high-aspect-ratio structures. The method includes the steps of placing the substrate into a plasma etching apparatus, wherein the plasma etching apparatus includes an upper electrode plate and a lower electrode plate; continuously supplying an upper source RF power and a DC power to the upper electrode plate; and discontinuously supplying a bias RF power to the lower electrode plate. When the bias RF power is switched to the off state, a large amount of secondary electrons pass through the bulk plasma and reach the substrate to neutralize the positive ions during the duration time of the off state (Toff).

Abstract: A method for increasing adhesion between polysilazane and silicon nitride is disclosed, comprising, providing a substrate comprising a trench, forming a silicon nitride liner layer on a bottom surface and a sidewall of the trench, performing a treating process to the silicon nitride liner layer for producing a hydrophilic surface with OH groups that can increase adhesion between the silicon nitride liner layer and a subsequently formed polysilazane coating layer, and forming a polysilazane coating layer into the trench and on the silicon nitride liner layer.

Abstract: A power device with trenched gate structure, includes: a substrate having a first face and a second face opposing to the first face, a body region of a first conductivity type disposed in the substrate, a base region of a second conductivity type disposed in the body region, a cathode region of the first conductivity type disposed in the base region, an anode region of the second conductivity type disposed in the substrate at the second face a trench disposed in the substrate and extending from the first face into the body region, and the cathode region encompassing the trench, wherein the trench has a wavelike sidewall, a gate structure disposed in the trench and an accumulation region disposed in the body region and along the wavelike sidewall. The wavelike sidewall can increase the base current of the bipolar transistor and increase the performance of the IGBT.

Abstract: A capacitor and a manufacturing method thereof are provided. The capacitor includes a first electrode, a first metal layer, a dielectric layer and a second electrode. The first electrode is disposed on a substrate. The first metal layer is disposed on the first electrode. The dielectric layer is disposed on the first metal layer, wherein the material of the first metal layer does not react with the material of the dielectric layer. The second electrode is disposed on the dielectric layer.

Abstract: A method for fabricating an integrated device with reduced plasma damage is disclosed, including providing a substrate, forming a structural layer on the substrate, forming a photoresist layer on the structural layer, and performing an etching process to the structural layer, wherein the photoresist layer is conductive to reduce plasma damage during the etching process.

Abstract: A method for forming a semiconductor structure with reduced line edge roughness is provided, including: providing a device layer with a patterned photoresist layer formed thereon; and performing a plasma etching process to pattern the device layer with the patterned photoresist layer formed thereon, forming a patterned device layer, wherein the plasma etching process is operated under a continuous on-stage voltage provided with a relative higher frequency and an on-off stage voltage with pulsing modulation provided with a relative lower frequency.

Abstract: The invention provides a method for forming a semiconductor device, including providing a substrate, forming a gate dielectric layer, forming a gate electrode on the gate dielectric layer, forming a spacer on sidewalls of the gate dielectric layer and the gate electrode, and using a rapid thermal process (RTP) apparatus comprising a plurality of lamps and a bias applying system to dope the substrate to form a source/drain region, wherein in the RTP apparatus, gaseous dopant species are illuminated by the lamps to be excited for transference gaseous dopant species to dopant ions and the dopant ions are moved by a bias from the bias applying system to be doped into the substrate.

Abstract: A wafer scrubber is disclosed, including a chamber, and a holder connecting to a spindle disposed in the chamber, wherein the holder supports a wafer, and the wafer spins to remove water on the wafer, and a mashed inner cup comprising a plurality of through holes disposed between the holder and a wall of the chamber, wherein the mashed inner cup receives water from a surface of the wafer and rotates around the spindle to release the water through the through holes.

Abstract: A bonding pad structure includes a semiconductor substrate having thereon a plurality of inter-metal dielectric (IMD) layers comprising at least a topmost IMD layer; a bondable metal pad layer disposed on a surface of the topmost IMD layer within a pad forming region; a passivation layer covering a periphery of the bondable metal pad layer and the surface of the topmost IMD layer; anda plurality of via plugs disposed in the topmost IMD layer within an annular region of the pad forming region, wherein the via plugs are not formed in a central region of the pad forming region.

Abstract: A fabricating method of a transistor is provided. A patterned sacrificed layer is formed on a substrate, wherein the patterned sacrificed layer includes a plurality of openings exposing the substrate. By using the patterned sacrificed layer as a mask, a doping process is performed on the substrate, thereby forming a doped source region and a doped drain region in the substrate exposed by the openings. A selective growth process is performed to form a source and a drain on the doped source region and the doped drain region, respectively. The patterned sacrificed layer is removed to expose the substrate between the source and the drain. A gate is formed on the substrate between the source and the drain.

Abstract: A method of forming an etch mask includes: providing a substrate having thereon a material layer to be etched; forming a hard mask layer consisting of a radiation-sensitive, single-layer resist material on the material layer; exposing the hard mask layer to actinic energy to change solvent solubility of exposed regions of the hard mask layer; and subjecting the hard mask layer to water treatment to remove the exposed regions of the hard mask layer, thereby forming a masking pattern consisting of unexposed regions of the hard mask layer.

Abstract: A semiconductor process is provided. An insulating layer is formed on a semiconductor substrate. A portion of the insulating layer is removed, so as to form a plurality of isolation structures and a mesh opening disposed between the isolation structures and exposing the semiconductor substrate. By performing a selective growth process, a semiconductor layer is formed from a surface of the semiconductor substrate exposed by the mesh opening, so that the isolation structures are disposed in the semiconductor layer.

Abstract: A wafer scrubber apparatus is disclosed, including a chamber, and holder connecting to a spindle disposed in the chamber, wherein the holder supports a wafer, and a gas purge pipe disposed at the top of a wall of the chamber, wherein the gas purge pipe comprises a plurality of gas injection holes facing downward to purge gas along the chamber wall making water flow along the chamber wall more smoothly and more quickly for preventing the water from scattering back to the wafer.

Abstract: The method for manufacturing a memory device is provided. The method includes: implanting a first impurity into the substrate adjacent to the gate conductor structure to form a source region on a first side of the gate conductor structure and a drain region on a second side of the gate conductor structure; implanting a second impurity into the substrate to form a halo implantation region disposed adjacent to the source region, wherein the halo implantation region has a doping concentration which does not degrade a data retention time of the memory device; and performing an annealing process to the drain region, forming a diffusion region under the drain region, wherein the process temperature of the annealing process is controlled to ensure that the diffusion region has a doping concentration substantially equal to a threshold concentration which maintains an electrical connection between the drain and the deep trench capacitor.

Abstract: A semiconductor structure includes a matrix, an integrated circuit and a scribe line. The matrix includes a scribe line region and a circuit region. The integrated circuit is disposed within the circuit region. The scribe line is disposed within the scribe line region and includes a crack stop trench which is disposed in the matrix and adjacent to the circuit region. The crack stop trench is parallel with one side of the circuit region and filled with a composite material in a form of a grid to form a crack stop structure.