Abstract: Methods for forming a gate using quantum dots are disclosed. More particularly, the present invention relates to a method for forming quantum dots for fabrication of an ultrafine semiconductor device includes a gate with quantum dots. The present invention is capable of forming quantum dots in uniform sizes and at uniform intervals so as to achieve an electrically stable device.

Abstract: A MOSFET device and a method for fabricating MOSFET devices are disclosed. The method includes providing a semiconductor device structure including a semiconductor device layer of a first conductivity type, and ion implanting a well structure of a second conductivity type in the semiconductor device layer, where the ion implanting includes providing a dopant concentration profile in a single mask implant sequence.

Abstract: Test structures and methods for semiconductor devices, lithography systems, and lithography processes are disclosed. In one embodiment, a method of manufacturing a semiconductor device includes using a lithography system to expose a layer of photosensitive material of a workpiece to energy through a lithography mask, the lithography mask including a plurality of first test patterns having a first phase shift and at least one plurality of second test patterns having at least one second phase shift. The layer of photosensitive material of the workpiece is developed, and features formed on the layer of photosensitive material from the plurality of first test patterns and the at least one plurality of second test patterns are measured to determine a optimal focus level or optimal dose of the lithography system for exposing the layer of photosensitive material of the workpiece.

Abstract: A line-form insulator is formed on a substrate and then the substrate is etched with the insulator used as a mask to form first trenches on both sides of the insulator. Side wall insulators are formed on the side walls of the first trenches, the substrate is etched with the insulator and side wall insulators used as a mask to form second trenches in the bottom of the first trenches. After, the substrate is oxidized with the insulator and side wall insulators used as an anti-oxidation mask to cause oxide regions formed on the adjacent side walls of the second trenches lying on both sides of the substrate to make contact with each other and the insulator and side wall insulators are removed. Then, a fin FET having a semiconductor region as a line-form fin is formed in the substrate.

Abstract: A method for forming vias in a substrate, including the following steps: (a) providing a substrate having a first surface and a second surface; (b) forming a groove on the substrate; (c) filling the groove with a conductive metal; (d) removing part of the substrate which surrounds the conductive metal, wherein the conductive metal is maintained so as to form an accommodating space between the conductive metal and the substrate; (e) forming an insulating material in the accommodating space; and (f) removing part of the second surface of the substrate to expose the conductive metal and the insulating material. In this way, thicker insulating material can be formed in the accommodating space, and the thickness of the insulating material in the accommodating space is even.

Abstract: A method of forming a semiconductor structure includes providing a substrate having a first feature and a second feature. A mask is formed over the substrate. The mask covers the first feature. An ion implantation process is performed to introduce ions of a non-doping element into the second feature. The mask is adapted to absorb ions impinging on the first feature. After the ion implantation process, an annealing process is performed.

Abstract: A semiconductor package substrate proposed by the invention includes a base body and a plurality of finger pads disposed on surface of the base body, wherein the finger pads are arranged in such a way that an angle is formed between connecting line of centers of two adjacent finger pads and the direction in which the finger pads are arranged. The finger pads are waterdrop shaped finger pads with arc ends and angle ends alternately disposed on surface of the substrate, alternately disposed waterdrop shaped finger pads and arc shaped finger pads, or alternately disposed arc shaped finger pads at a predetermined spacing. According to the present invention, distance between adjacent finger pads is reduced and problem of short circuit as a result of erroneous contact between bonding wire and adjacent finger pad is prevented.

Abstract: Multi-layered carbon-based hardmask and method to form the same. The multi-layered carbon-based hardmask includes at least top and bottom carbon-based hardmask layers having different refractive indexes. The top and bottom carbon-based hardmask layer thicknesses and refractive indexes are tuned so that the top carbon-based hardmask layer serves as an anti-reflective coating (ARC) layer.

Abstract: A method of manufacturing a thin film transistor substrate includes forming a transistor thin layer pattern, forming a protecting layer, forming a photoresist film, forming a pixel electrode and a conductive layer that are separated from each other, stripping a photoresist pattern to remove the conductive layer using a stripping composition and dissolving the conductive layer. The method of manufacturing a thin film transistor substrate is capable of improving an efficiency of manufacturing process of the thin film transistor substrate. In addition, the stripping composition is recycled.

Abstract: A semiconductor device of the present invention is manufactured by the following steps: forming a single-crystal semiconductor layer over a substrate having an insulating surface; irradiating a region of the single-crystal semiconductor layer with laser light; forming a circuit of a pixel portion using a region of the single-crystal semiconductor layer which is not irradiated with the laser light; and forming a driver circuit for driving the circuit of the pixel portion using the region of the single-crystal semiconductor layer which is irradiated with the laser light. Thus, a semiconductor device using a single-crystal semiconductor layer which is suitable for a peripheral driver circuit region and a single-crystal semiconductor layer which is suitable for a pixel region can be provided.

Abstract: A method for forming a through-silicon via bandpass filter includes forming a substrate comprising a silicon layer and providing a metal layer on a bottom side of the silicon layer. Additionally, the method includes providing a dielectric layer on a top side of the silicon layer and forming a top-side interconnect of the through-silicon via bandpass filter on a surface of the dielectric layer. Further, the method includes forming a plurality of contacts in the dielectric layer in contact with the top-side interconnect and forming a plurality through-silicon vias through the substrate and in contact with the plurality of contacts, respectively, and the metal layer.

Abstract: There is provided a method of fabricating semiconductor devices that allows ion implantation to be performed at high temperature with ions accelerated with high energy to help to introduce dopant in a semiconductor substrate, in particular a SiC semiconductor substrate, at a selected region to sufficient depth. To achieve this the method includes the steps of: providing the semiconductor substrate at a surface thereof with a mask layer including a polyimide resin film, or a SiO2 film and a thin metal film; and introducing dopant ions.

Abstract: Methods for producing a junction termination extension surrounding the edge of a cathode or anode junction in a semiconductor substrate, where the junction termination extension has a controlled arbitrary lateral doping profile and a controlled arbitrary lateral width, are provided. A photosensitive material is illuminated through a photomask having a pattern of opaque and clear spaces therein, the photomask being separated from the photosensitive material so that the light diffuses before striking the photosensitive material. After processing, the photosensitive material so exposed produces a laterally tapered implant mask. Dopants are introduced into the semiconductor material and follow a shape of the laterally tapered implant mask to create a controlled arbitrary lateral doping profile and a controlled lateral width in the junction termination extension in the semiconductor.

Abstract: According to the present invention, there is provided a semiconductor device including a first conductive type semiconductor substrate, a gate electrode formed over the semiconductor substrate via a gate insulator, a first conductive impurity region buried in the semiconductor substrate, the first conductive impurity region being both sides of an extend plane, the extend plane being extended from side-walls of the gate electrode into the semiconductor substrate and a second conductive type source/drain region partially overlapping with the first conductive impurity region and extending from an end of the gate electrode at the semiconductor substrate to an outer region in the semiconductor substrate, wherein a first conductive impurity concentration at a prescribed depth in the overlapping portion between the first conductive impurity region and the source/drain region is lower than the first conductive impurity concentration in the first conductive impurity region except the overlapping portion corresponding

Abstract: A complementary metal oxide semiconductor (CMOS) image sensor (CIS) and a method for fabricating the same. A method for fabricating a CIS includes implanting first conductive type dopants in a semiconductor substrate to form a photodiode region in a surface of the semiconductor substrate, implanting second conductive type dopants in the photo diode region to form a second conductive type diffusion region, and implanting fluorine ions in the second conductive type diffusion region to form a fluorine diffusion region.

Abstract: A method for manufacturing a semiconductor memory device using asymmetric junction ion implantation, including performing ion implantation for adjusting a threshold voltage to a semiconductor substrate, forming a gate stack on the semiconductor substrate to define a storage node junction region and a bit line junction region, implanting a first conductive impurity ion and a second conductive impurity ion using a mask layer pattern covering the storage node junction region while exposing the bit line junction region, forming a gate spacer layer at both sides of the gate stack, and implanting the first conductive impurity ion using the gate stack and the gate spacer layer as an ion implantation mask layer to form a storage node junction region and a bit line junction region having different impurity concentrations, and different junction depths from each other.

Abstract: In a process for producing a TFT display, a polysilicon layer is patterned to define a first and a second TFT regions. A first doping material is implanted into a first exposed portion in the first TFT region to define a first doped region and a first channel region, and implanted into a second exposed portion in the second TFT region to define a second doped region and a second channel region. A second doping material is implanted into a third exposed portion smaller than the first exposed portion to form first source/drain regions and simultaneously define a first LDD region in the first TFT region. A first and a second gate structures are formed over the first and the second channel regions, respectively. In a certain direction, the first gate structure is longer than the first channel, and the second gate structure isn't longer than the second channel region.

Abstract: A process for realizing TFT devices on a substrate comprises the steps of: forming on the substrate, in cascade, an amorphous silicon layer and a heavily doped amorphous silicon layer, forming a photolithographic mask on the heavily doped amorphous silicon layer provided with an opening, removing the heavily doped amorphous silicon layer through the opening for realizing opposite portions of the heavily doped amorphous silicon layer whose cross dimensions decrease as long as they depart from the amorphous silicon layer, removing the photolithographic mask, carrying out a diffusion and activation step of the dopant contained in the portions of the heavily doped amorphous silicon layer inside the amorphous silicon layer, for realizing source/drain regions of said TFT device.

Abstract: A liquid crystal display device and a fabricating method thereof for simplifying a process and improving an aperture ratio are disclosed, including forming a first mask pattern group including a gate line, a gate electrode and a common line; forming a second mask pattern group including a semiconductor pattern and a source/drain pattern having a data line, a source electrode and a drain electrode overlapped thereon on the gate insulating film using a second mask; and forming a third mask pattern group including and a pixel electrode making an interface with the protective film in the pixel hole to be connected to the drain electrode, thereby forming a horizontal electric field with the common electrode, using a third mask.

Abstract: Methods of patterning features of semiconductor devices and methods of processing and fabricating semiconductor devices are disclosed. In one embodiment, a method of processing a semiconductor device includes forming first sidewall spacers on a first hard mask, removing the first hard mask, and forming a first material layer over the first sidewall spacers. A second hard mask is formed over the first material layer and the first sidewall spacers. Second sidewall spacers are formed on the second hard mask, and the second hard mask is removed. At least the first sidewall spacers are patterned using the second sidewall spacers as a mask.

Abstract: A method of sealing a microelectromechanical system (MEMS) device from ambient conditions is described, wherein the MEMS device is formed on a substrate and a substantially hermetic seal is formed as part of the MEMS device manufacturing process. The method comprises forming a metal seal on the substrate proximate a perimeter of the MEMS device using a method such as photolithography. The metal seal is formed on the substrate while the MEMS device retains a sacrificial layer between conductive members of MEMS elements, and the sacrificial layer is removed after formation of the seal and prior to attachment of a backplane.

Abstract: A method of creating a sensor that may include applying a first conductive material on a first portion of a substrate to form a reference electrode and depositing a first mask over the substrate, the first mask having an opening that exposes the reference electrode and a second portion of the substrate. The method may also include depositing a second conductive material into the opening in the first mask, the second conductive material being in direct contact with the reference electrode and depositing a second mask over the second conductive material, the second mask having an opening over the second portion of the substrate, the opening exposing a portion of the second conductive material, which forms a working surface to receive a fluid of interest.

Abstract: A method for fabricating a device is disclosed. The method includes providing a substrate; forming a thin film on the substrate; forming a photoresistable layer on the thin film; irradiating light onto the photoresistable layer through a photo mask having a transmissive region, a semi-transmissive region, a diffractive region and an interceptive region, and developing the photoresistable layer to form a photoresist pattern having at least three different thicknesses. With the above-described process, a liquid crystal display device (LCD), for example, can be manufactured using three photo masks.

Abstract: A barrier layer forming method includes providing a porous dielectric layer over a substrate, the dielectric layer having a surface with exposed pores, and treating the dielectric layer with a plasma formed from a methane-containing gas. The treating seals the exposed pores. The method includes depositing a barrier layer over the surface, the barrier layer being continuous over the sealed pores. The porous dielectric may be low K. The plasma may be formed at a bias of at least about 100 volts.

Abstract: A process and structure for a metal interconnect includes providing a substrate with a first electric conductor, forming a first dielectric layer and a first patterned hard mask, using the first patterned hard mask to form a first opening and a second electric conductor, forming a second dielectric layer and a second patterned hard mask, using the second patterned hard mask as an etching mask and using a first patterned hard mask as an etch stop layer to form a second opening and a third electric conductor.

Abstract: A semiconductor device includes: a semiconductor layer 10; a semiconductor region 15s of a first conductivity type defined on the surface 10s of the semiconductor layer; a semiconductor region 14s of a second conductivity type defined on the surface 10s of the semiconductor layer to surround the semiconductor region 15s; and a conductor 19 with a conductive surface 19s to contact with the semiconductor regions 15s and 14s. The semiconductor layer 10 includes silicon carbide. At least one of the semiconductor region 15s and the conductive surface 19s is not circular. The semiconductor region 15s and the conductive surface 19s are shaped such that as the degree of misalignment between the conductive surface 19s and the semiconductor region 15s increases from zero through one-third of the width of the conductive surface 19s, a portion of the profile of the conductive surface 19s that crosses the semiconductor region 15s has smoothly changing lengths.

Abstract: A method that includes providing a semiconductor substrate having a mask on a surface thereof. The mask includes a first region having no masking elements and a second region having a plurality of masking elements. Each of the plurality of masking elements has a dimension that is equal to a first length, the first length less than twice a diffusion length of a dopant. The method further includes bombarding the semiconductor substrate and masking element with ions of the dopant. The ions form a first impurity concentration in the first region and a second impurity concentration in the second region.

Abstract: In embodiments, a method for manufacturing a semiconductor device may include forming a diffusion preventing layer on a semiconductor substrate having a conductive layer, forming an intermetallic insulating layer on the diffusion preventing layer, forming a trench photo resist layer formed above the intermetallic insulating layer of a first photo resist material, forming a via hole photo resist layer of a second photo resist material at an upper portion and a sidewall in a contact hole of the trench photo resist layer, etching the intermetallic insulating layer and the diffusion preventing layer using the via hole photo resist layer and the trench photo resist layer to substantially simultaneously form a via hole and a trench, and filling the via hole and the trench with a metal thin film to form a metal line.

Abstract: A gate insulating film (13) and a gate electrode (14) of non-single crystalline silicon for forming an nMOS transistor are provided on a silicon substrate (10). Using the gate electrode (14) as a mask, n-type dopants having a relatively large mass number (70 or more) such as As ions or Sb ions are implanted, to form a source/drain region of the nMOS transistor, whereby the gate electrode (14) is amorphized. Subsequently, a silicon oxide film (40) is provided to cover the gate electrode (14), at a temperature which is less than the one at which recrystallization of the gate electrode (14) occurs. Thereafter, thermal processing is performed at a temperature of about 1000° C., whereby high compressive residual stress is exerted on the gate electrode (14), and high tensile stress is applied to a channel region under the gate electrode (14). As a result, carrier mobility of the nMOS transistor is enhanced.

Abstract: A process and structure for a metal interconnect includes providing a substrate with a first electric conductor, forming a first dielectric layer and a first patterned hard mask, using the first patterned hard mask to form a first opening and a second electric conductor, forming a second dielectric layer and a second patterned hard mask, using the second patterned hard mask as an etching mask and using a first patterned hard mask as an etch stop layer to form a second opening and a third electric conductor.

Abstract: A method of manufacturing a semiconductor device including forming an ONO film on a semiconductor substrate and a hard mask layer on the ONO film, forming a trench by etching the hard mask layer and the ONO film on a field region of the semiconductor substrate using a photo etch process and etching the field region of the semiconductor substrate, and forming a device separator at the trench. The method also includes exposing the ONO film by removing the hard mask layer on the ONO film, and leaving the ONO film only on a prospective SONOS gate in a cell region of the semiconductor substrate and removing the ONO film the remainder region thereof. The method further includes forming a gate oxide film on the semiconductor substrate at an outside of the ONO film, and forming a gate electrode on the gate oxide film and the ONO film, respectively.

Abstract: A mask includes a silicon member, and a portion defining an opening penetrating the silicon member; and the corner of the opening is rounded.

Abstract: A method for fabricating a high-density silicon-on-insulator (SOI) cross-point memory array and an array structure are provided. The method includes the following steps: selectively forming a hard mask on an SOI substrate, defining memory areas, active device areas, and top electrode areas; etching to remove the exposed silicon (Si) surfaces; selectively forming metal sidewalls adjacent the hard mask; filling the memory areas with memory resistor material; removing the hard mask, exposing the underlying Si active device areas; forming an overlying layer of oxide; etching the oxide to form contact holes to the active device areas; forming diodes in the contact holes; and, forming bottom electrode lines overlying the diodes.

Abstract: A method of forming a MOS transistor in an upper surface of a semiconductor substrate. A gate oxide layer covers the upper surface of the substrate. A gate stack including one or more thin film layers covers the gate oxide layer. A gate electrode pattern is partially etched into the gate stack, the partial etching step being completed before any of the gate oxide layer is exposed. Sidewall spacers are formed on edge surfaces of the partially formed gate electrode. Source and drain regions are created by ion implantation using the partially etched gate electrode and the sidewall spacers as a mask. The sidewall spacers are removed and lightly doped drain regions are formed by ion implantation using the partially etched gate electrode as a mask.

Abstract: A semiconductor device includes a semiconductor chip which has a top surface, a conductive member which includes a first portion which is located on the electrode pad and a second portion which is extended from the first portion, and a sealing resin which seals the top surface of the semiconductor chip and the conductive member. A top surface of the second portion is exposed from the sealing resin and a part of the top surface of the second portion is concaved from a surface of the sealing resin. An external electrode is formed on the top surface of the second portion.

Abstract: Methods and structures to reduce in semiconductor packages the length of critical electrical connections between bond pads on one or multiple semiconductor chips and wire landing pads on a substrate have been achieved. An electrical connection becomes critical if high current, high speed or radio frequency signals have to be transported. Moving the wire landing pads of critical connections on the substrate closer to the semiconductor chip utilizing unpopulated spaces of an array grid design reduces the length of said wires. This could be a ball grid array (BGA) or any other kind of grid array. Said methods and structures invented are applicable to single-chip modules and to multi-chip modules. The design of the grid array has to be modified to provide free spaces for the wire landing pads of critical electrical connections within the grid array close to the semiconductor chip as required by the design rules. The design change can be done without increasing the number of solder balls or solder pins, etc.