Abstract: The present invention provides a method of forming a semiconductor device. First, a substrate is provided and an STI is forming in the substrate to define a plurality of active regions. Then a first etching process is performed to form a bit line contact opening, which is corresponding to one of the active regions. A second etching process is performed to remove a part of the active region and its adjacent STI so a top surface of active region is higher than a top surface of the STI. Next, a bit line contact is formed in the opening. The present invention further provides a semiconductor structure.

Abstract: The present invention provides a method for fabricating a semiconductor structure. A multilayer structure on is formed a substrate, the multilayer structure includes at least a first dielectric layer, a second dielectric layer and an amorphous silicon layer, next, a first etching step is performed, to forma first recess in the amorphous silicon layer and in the second dielectric layer, parts of the first dielectric layer is exposed by the first recess, afterwards, a hard mask layer is formed in the first recess, a second etching step is then performed to remove the hard mask layer and to expose a surface of the first dielectric layer, and a third etching step is performed with the remaining hard mask layer, to remove a portion of the first dielectric layer, so as to form a second recess in the first dielectric layer.

Abstract: The present invention relates to a method of forming a memory capacitor. A substrate is provided with a plurality of storage node contacts. A patterned supporting structure is formed on the substrate, following by forming a bottom electrode conformally on surface of plural openings in the patterned supporting structure, thereby contacting the storage node contacts. A sacrificial layer is formed in the opening. A soft etching process is performed to remove the bottom electrode on top and partial sidewall of the patterned supporting structure, wherein the soft etching process includes using a fluoride containing compound, a nitrogen and hydrogen containing compound and an oxygen containing compound. The sacrificial layer is completely removed away. A capacitor dielectric layer and a top electrode are formed on the bottom electrode layer.

Abstract: A method for fabricating a semiconductor device includes the following steps. First, a contact structure is formed in the insulating layer. Preferably, the contact structure includes a bottom portion in part of the insulating layer and a top portion on part of the bottom portion and extending to cover part of the insulating layer. Next, a dielectric layer is formed on the bottom portion and the top portion, part of the dielectric layer is removed to form a first opening exposing part of the top portion and part of the bottom portion, and a capacitor is formed in the first opening and contacting the pad portion and the contact portion directly.

Abstract: Cells derived from postpartum placenta and methods for their isolation are provided by the invention. The invention further provides cultures and compositions of the placenta-derived cells. The placenta-derived cells of the invention have a plethora of uses, including but not limited to research, diagnostic, and therapeutic applications.

Abstract: A method of fabricating a buried word line structure includes providing a substrate with a word line trench therein. Two source/drain doped regions are disposed in the substrate at two sides of the word line trench. Later, a silicon oxide layer is formed to cover the word line trench. A titanium nitride layer is formed to cover the silicon oxide layer. Next, a tilt ion implantation process is performed to implant silicon atoms into the titanium nitride layer to transform part of the titanium nitride layer into a titanium silicon nitride layer. A conductive layer is formed in the word line trench. Subsequently, part of the conductive layer, part of the titanium silicon nitride layer and part of the silicon oxide layer are removed to form a recess. Finally, a cap layer fills in the recess.

Abstract: A method of fabricating a buried word line structure includes providing a substrate with a word line trench therein. Two source/drain doped regions are disposed in the substrate at two sides of the word line trench. Later, a silicon oxide layer is formed to cover the word line trench. A titanium nitride layer is formed to cover the silicon oxide layer. Next, a tilt ion implantation process is performed to implant silicon atoms into the titanium nitride layer to transform part of the titanium nitride layer into a titanium silicon nitride layer. A conductive layer is formed in the word line trench. Subsequently, part of the conductive layer, part of the titanium silicon nitride layer and part of the silicon oxide layer are removed to form a recess. Finally, a cap layer fills in the recess.

Abstract: A semiconductor memory device includes a substrate, plural gates, plural cell plugs, a capacitor structure and a stacked structure. The gates are disposed in the substrate, and the cell plugs are disposed on the substrate, to electrically connect the substrate at two sides of each gate. The capacitor structure includes plural capacitors, and each capacitor is electrically connected each cell plug. The stacked structure covers the capacitor structure, and the stacked structure includes a semiconductor layer, a conductive layer on the semiconductor layer and an insulating layer stacked on the conductive layer. Two gaps are defined respectively between a side portion of the insulating layer and a lateral portion of the conductive layer at two sides of the capacitor structure, and the two gaps have different lengths.

Abstract: A high-efficiency method for producing metal from metal oxide by carbothermic reduction includes step in which a holed cake is provided, which has a composition comprising a metal oxide, a carbonaceous reducing agent, and a binder, and the holed cake has a plurality of holes. The method continues with step in which the holed cake is placed in a high-temperature furnace for carbothermic reduction, to reduce the metal oxide in the holed cake into a metal.

Abstract: Methods of in-loop deblocking filter for high dynamic range (HDR) video compression are disclosed. HDR processing and standard dynamic range (SDR) processing adopt different electro-optical transfer function (EOTF) to convert digital code words to linear luminance. For compressing HDR video, EOTF is proposed to be involved in the selection of two deblocking parameters, ? and tC, which control the strength of deblocking filter. In local activity checking for filter decisions, the calculated local signal characteristics and the thresholds are adjusted according to EOTF. After deblocking filter, the clipping range is modified based on EOTF. The chroma deblocking filter is also extended to inter-inter block boundary.

Abstract: A method of manufacturing contacts is provided in the present invention, which include the steps of forming a plurality of mask bars on a substrate, forming a circular mask surrounding each mask bar, wherein the circular masks connect each other and define a plurality of opening patterns collectively with the mask bars, using the mask bars and the circular masks as etch masks to perform an etch process and to transfer the opening patterns and form a plurality recesses in the substrate, and filling up the recesses with metal to form contacts.

Abstract: A method for fabricating a capacitor includes providing a substrate and a first etching stop layer on the substrate; forming a plurality of first spacers on the first etching stop layer; forming an organic layer and a second etching stop layer sequentially on the first spacers, the organic layer covering the first spacers; forming a plurality of second spacers on the second etching stop layer, each second spacer crossing the first spacers; transferring a pattern of the second spacers to the organic layer to form an organic pattern; performing an etching process using the organic pattern and the first spacers as a mask to form an etching stop pattern and remove the second etching stop layer; transferring the etching stop pattern to the substrate to form a plurality of through holes.

Abstract: The present invention discloses a semiconductor structure with capacitor landing pad and a method for fabricating a capacitor landing pad. The semiconductor structure with capacitor landing pad includes a substrate having a plurality of contact structures, a first dielectric layer disposed on the substrate and the contact structures, and a plurality of capacitor landing pads, each of the capacitor landing pads being located in the first dielectric layer and electrically connected to the contact structure, wherein the capacitor landing pads presents a shape of a wide top and a narrow bottom and a top surface of the capacitor landing pads have a concave shape.

Abstract: A method of fabricating an isolation structure is provided. A first oxide layer and a first, second, and third hard mask layers are formed on a substrate. A patterned third hard mask layer is formed. Second oxide layers are formed on sidewalls of the patterned third hard mask layer and a fourth hard mask layer is formed between the second oxide layers. The second oxide layers and the second hard mask layer are removed using the patterned third hard mask layer and the fourth hard mask layer as a mask, to form a patterned second hard mask layer. The patterned third hard mask layer and the fourth hard mask layer are removed. A portion of the patterned second hard mask layer is removed to form trench patterns. A patterned first hard mask layer and first oxide layer, and trenches located in the substrate are defined. An isolation material is formed.

Abstract: Cells derived from postpartum placenta and methods for their isolation are provided by the invention. The invention further provides cultures and compositions of the placenta-derived cells. The placenta-derived cells of the invention have a plethora of uses, including but not limited to research, diagnostic, and therapeutic applications.

Abstract: A patterning method is disclosed. A substrate having a hard mask layer and a first material layer formed thereon is provided. The first material layer is patterned into first array patterns and first peripheral patterns. The first array patterns are further transferred into first spacer patterns. Subsequently, a planarization layer and a second material layer are successively formed on the substrate. The second material layer is patterned into second array patterns and second peripheral patterns. The second array patterns are further transferred into second spacer patterns. The second spacer patterns partially overlap the first spacer patterns. The second peripheral patterns do not overlap the first peripheral pattern. The first spacer patterns not overlapped by the second spacer patterns are removed to obtain third array patterns. The hard mask layer is then etched using the third array patterns, the second peripheral patterns and the first peripheral patterns as an etching mask.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes a substrate having a scribe line region. A material layer is formed on the scribe line region and has a rectangular region defined therein. The rectangular region has a pair of first edges parallel with a widthwise direction of the scribe line region and a pair of second edges parallel with a lengthwise direction of the scribe line region. A pair of first alignment features is formed in the material layer along the first edges, and a pair of second alignment features is formed in the material layer along the second edges. The space between the pair of first alignment features is larger than a space between the pair of the second alignment features.

Abstract: A method of fabricating an STI trench includes providing a substrate. Later, a first mask is formed to cover the substrate. The first mask includes numerous sub-masks. A first trench is disposed between each sub-mask. Subsequently, a protective layer is formed to fill up the first trench. Then, a second mask is formed to cover the first mask. The second mask includes an opening. The sub-mask directly disposed under the opening is defined as a joint STI pattern. After that, the joint STI pattern is removed to transform the first mask into a third mask. Later, the second mask is removed followed by removing the protective layer. Finally, part of the substrate is removed by taking the third mask as a mask to form numerous STI trenches.

Abstract: A semiconductor device and method of forming the same, the semiconductor device includes bit lines, a transistor, a dielectric layer, plugs and a capping layer. The bit lines are disposed on a substrate within a cell region thereof, and the transistor is disposed on the substrate within a periphery region. The plugs are disposed in the dielectric layer, within the cell region and the periphery region respectively. The capping layer is disposed on the dielectric layer, and the capping layer disposed within the periphery region is between those plugs. That is, a portion of the dielectric layer is therefore between the capping layer and the transistor.

Abstract: A patterning method is disclosed. A hard mask layer, a lower pattern transfer layer, an upper pattern transfer layer are formed on a target layer. A first SARP process is performed to pattern the upper pattern transfer layer into an upper pattern mask. A second SARP process is performed to pattern the lower pattern transfer layer into a lower pattern mask. The upper pattern mask and the lower pattern mask define hole patterns. The hole patterns is filled with a dielectric layer. The dielectric layer and the upper pattern mask are etched back until the lower pattern mask is exposed. The lower pattern mask is removed, thereby forming island patterns. Using the island patterns as an etching hard mask, the hard mask layer is patterned into hard mask patterns. Using the hard mask patterns as an etching hard mask, the target layer is patterned into target patterns.