Abstract: A method for fabricating a self-aligned bipolar transistor, wherein a substrate having an epitaxial layer formed thereon as a base is provided. After this, a first dielectric layer, a second dielectric layer are sequentially formed on the epitaxial layer, followed by forming an opening in the second dielectric layer. A conductive spacer is formed on the sidewall of the opening. Using the second dielectric layer and the conductive spacer as a mask, a first dielectric layer in the opening is removed. A conductive layer is then formed in the opening as an emitter, followed by completely removing the second dielectric layer. A doping is conducted on the emitter. Using the emitter and the conductive spacer as a mask, a part of the first dielectric layer is removed. Further using the emitter and the conductive spacer as a mask, another doping is conducted to form a part of the epitaxial layer as a base contact region.

Abstract: A variable capacitor comprising a substrate having a first type ion-doped buried layer, a first type ion-doped well, a second type ion-doped region and a conductive layer thereon. The first type ion-doped well is formed within the substrate. The first type ion-doped well has a cavity. The first type ion-doped buried layer is in the substrate underneath the first type ion-doped well. The first type ion-doped buried layer and the first type ion-doped well are connected. The second type ion-doped region is at the bottom of the cavity of the first type ion-doped well. The conductive layer is above and in connection with the first type ion-doped buried layer.

Abstract: A variable capacitor comprising a substrate having a first type ion-doped buried layer, a first type ion-doped well, a second type ion-doped region and a conductive layer thereon. The first type ion-doped well is formed within the substrate. The first type ion-doped well has a cavity. The first type ion-doped buried layer is in the substrate underneath the first type ion-doped well. The first type ion-doped buried layer and the first type ion-doped well are connected. The second type ion-doped region is at the bottom of the cavity of the first type ion-doped well. The conductive layer is above and in connection with the first type ion-doped buried layer.

Abstract: An anti-reflection layer and method of manufacture. A silicon substrate has a conductive layer formed thereon. Plasma-enhanced chemical vapor deposition is performed to form a graded silicon oxynitride layer over the conductive layer. During silicon oxynitride deposition, concentration of one of the reactive gases nitrous oxide is gradually reduced so that the graded silicon oxynitride layer is oxygen-rich near bottom but nitrogen-rich near the top.

Abstract: An anti-reflection layer and method of manufacture. A silicon substrate has a conductive layer formed thereon. Plasma-enhanced chemical vapor deposition is performed to form a graded silicon oxynitride layer over the conductive layer. During silicon oxynitride deposition, concentration of one of the reactive gases nitrous oxide is gradually reduced so that the graded silicon oxynitride layer is oxygen-rich near bottom but nitrogen-rich near the top.

Abstract: A method for fabricating a self-aligned bipolar transistor, wherein a substrate having an epitaxial layer formed thereon as a base is provided. After this, a first dielectric layer, a second dielectric layer are sequentially formed on the epitaxial layer, followed by forming an opening in the second dielectric layer. A conductive spacer is formed on the sidewall of the opening. Using the second dielectric layer and the conductive spacer as a mask, a first dielectric layer in the opening is removed. A conductive layer is then formed in the opening as an emitter, followed by completely removing the second dielectric layer. A doping is conducted on the emitter. Using the emitter and the conductive spacer as a mask, a part of the first dielectric layer is removed. Further using the emitter and the conductive spacer as a mask, another doping is conducted to form a part of the epitaxial layer as a base contact region.

Abstract: A structure of a DRAM and a manufacturing process therefor, suitable for a substrate on which a plurality of word lines and a plurality of source/drain regions on sides of each of these word lines are formed. A plurality of bit line contacts and a plurality of node contacts are formed in electric contact with the source/drain regions. A first patterned insulating layer is formed on the substrate, in which a plurality of openings are formed in the insulating layer to expose the bit line contacts. The substrate is covered with a first conductive layer and a second insulating layer in sequence. The second insulating layer, the first conductive layer and the first insulating layer are patterned in sequence to form a plurality of bit line stacked structures and a plurality of bit lines electrically connecting to the bit contacts, exposing the node contacts. As a result, the bit line stacked structure forms a plurality of trenches and the bit line stacked structure is orthogonal to the word lines.

Abstract: A method for monitoring bipolar junction transistor emitter window etching process is disclosed. The method at least includes the following steps. First of all, a substrate is provided having a silicon oxide layer thereon and a silicon nitride layer on the silicon oxide layer. Then, a semiconductor layer is deposited on the silicon nitride layer. Next, a conductive region of a first conductivity type is formed in the semiconductor layer. Then, a dielectric layer is formed on the semiconductor layer. Then, the dielectric layer and the semiconductor layer are anisotropically etched to stop on the silicon oxide layer to define an emitter region of the bipolar junction transistor. Finally, the silicon oxide layer is isotropically etched.

Abstract: A self-aligned bit-line contact opening and node contact opening fabrication process having the following features: Etching of the periphery MOS spacer is performed before ion implantation of the periphery MOS source/drain region, using the same photoresist layer as a mask. A self-aligned bit-line (node) contact opening and a periphery gate contact opening, above the periphery MOS gate, are formed simultaneously. The etching of the memory cell MOS spacer is performed after the self-aligned bit-line (node) contact opening has been formed. At the same time, the cap layer above the periphery MOS gate, exposed by the periphery gate contact opening, is etched through.

Abstract: The present invention provides a method of making self-aligned bit-lines on a semiconductor wafer. The semiconductor wafer comprises a silicon substrate, a plurality of word-lines located on the silicon substrate and a first dielectric layer that covers each word-line. A plurality of bit-line contacts are formed that are level with the surface of the first dielectric layer. A second dielectric layer is formed on the surface of the semiconductor wafer and a plurality of node contacts are formed in the second and first dielectric layer, which are leveled with the surface of the second dielectric layer. Portions of the second dielectric layer are removed to make the top portion of each node contact higher than the surface of the second dielectric layer. A spacer is formed around this top portion of each node contact.

Abstract: A structure of a DRAM and a manufacturing process therefor, suitable for a substrate on which a plurality of word lines and a plurality of source/drain regions on sides of each of these word lines are formed. A plurality of bit line contacts and a plurality of node contacts are formed in electric contact with the source/drain regions. A first patterned insulating layer is formed on the substrate, in which a plurality of openings are formed in the insulating layer to expose the bit line contacts. The substrate is covered with a first conductive layer and a second insulating layer in sequence. The second insulating layer, the first conductive layer and the first insulating layer are patterned in sequence to form a plurality of bit line stacked structures and a plurality of bit lines electrically connecting to the bit contacts, exposing the node contacts. As a result, the bit line stacked structure forms a plurality of trenches and the bit line stacked structure is orthogonal to the word lines.

Abstract: A structure of a DRAM and a manufacturing process therefor, suitable for a substrate on which a plurality of word lines and a plurality of source/drain regions on sides of each of these word lines are formed. A plurality of bit line contacts and a plurality of node contacts are formed in electric contact with the source/drain regions. A first patterned insulating layer is formed on the substrate, in which a plurality of openings are formed in the insulating layer to expose the bit line contacts. The substrate is covered with a first conductive layer and a second insulating layer in sequence. The second insulating layer, the first conductive layer and the first insulating layer are patterned in sequence to form a plurality of bit line stacked structures and a plurality of bit lines electrically connecting to the bit contacts, exposing the node contacts. As a result, the bit line stacked structure forms a plurality of trenches and the bit line stacked structure is orthogonal to the word lines.

Abstract: A structure of a DRAM and a manufacturing process therefor, suitable for a substrate on which a plurality of word lines and a plurality of source/drain regions on sides of each of these word lines are formed. A plurality of bit line contacts and a plurality of node contacts are formed in electric contact with the source/drain regions. A first patterned insulating layer is formed on the substrate, in which a plurality of openings are formed in the insulating layer to expose the bit line contacts. The substrate is covered with a first conductive layer and a second insulating layer in sequence. The second insulating layer, the first conductive layer and the first insulating layer are patterned in sequence to form a plurality of bit line stacked structures and a plurality of bit lines electrically connecting to the bit contacts, exposing the node contacts. As a result, the bit line stacked structure forms a plurality of trenches and the bit line stacked structure is orthogonal to the word lines.

Abstract: An anti-reflection layer and method of manufacture. A silicon substrate has a conductive layer formed thereon. Plasma-enhanced chemical vapor deposition is performed to form a graded silicon oxynitride layer over the conductive layer. During silicon oxynitride deposition, concentration of one of the reactive gases nitrous oxide is gradually reduced so that the graded silicon oxynitride layer is oxygen-rich near bottom but nitrogen-rich near the top.

Abstract: The present invention provides a method of making self-aligned bit-lines on a substrate, the surface of which comprises a dielectric layer having a plurality of node contact holes and bit-line contact holes. A first conducting layer is formed on the surface of the substrate, filling each node contact hole and bit-line contact hole. Next, a protecting layer is formed over the first conducting layer. The protecting layer and the first conducting layer are etched to form each node contact and bit-line contact. A spacer is formed around each node contact. A second dielectric layer is formed on the wafer, and then etched down to the first dielectric layer and to the surface of each bit-line contact, forming a trench in the second dielectric layer.

Abstract: A semiconductor fabrication method is provided for the fabrication of an isolation structure including, a shallow-trench isolation (STI) structure in an integrated circuit. This method is characterized by the increase in the thickness of the adhesive layer over that of the prior art and also in the use of thermal oxidation process to form the STI structure. The thick adhesive layer can thus resist the stress from thermal expansion of the various component layers in the integrated circuit during heat treatment. Moreover, the resulting STI structure is not formed with recessed edge portions since the hydrofluoric (HF) enchant acts on the silicon dioxide plug in the STI structure with substantially the same etching irate as on the adhesive layer. Moreover, this method includes no chemical-mechanical polish (CMP) process so the problem of scratches on the surface of the silicon dioxide plug as seen in the case of the prior art is avoided.

Abstract: A method for manufacturing a bit line and a bit line contact. A semiconductor substrate having a word line thereon is provided. Oxide spacers are formed on the sidewalls of the word line. A dielectric layer that covers the word line is formed over the entire substrate. A cap layer is next formed over the dielectric layer. The cap layer and the dielectric layer are patterned to form a trench in the dielectric layer. Silicon nitride spacers are formed on the sidewalls of the trench. In the subsequent step, the dielectric layer is etched down the trench to form a contact window that exposes a portion of the substrate. Polysilicon material is deposited into the contact window to form a polysilicon plug, and then metal silicide material is deposited into the trench above the plug to form a metal silicide layer.

Abstract: A semiconductor fabrication method is provided for the fabrication of an isolation structure including a shallow-trench isolation (STI) structure in an integrated circuit. This method is characterized by the increase in the thickness of the adhesive layer over that of the prior art and also in the use of thermal oxidation process to form the STI structure. The thick adhesive layer can thus resist the stress from thermal expansion of the various component layers in the integrated circuit during heat treatment. Moreover, the resulting STI structure is not formed with recessed edge portions since the hydrofluoric (HF) etchant acts on the silicon dioxide plug in the STI structure with substantially the same etching rate as on the adhesive layer. Moreover, this method includes no chemical-mechanical polish (CMP) process, so the problem of scratches on the surface of the silicon dioxide plug as seen in the case of the prior art is avoided.

Abstract: A method of fabricating a self-aligned contact window structure is described in which a substrate is provided with a plurality of gates formed on the substrate and a plurality of lightly doped regions is formed in the substrate on both sides of the gate. A first dielectric layer of a certain thickness is then formed on the substrate with the surface of the first dielectric layer being lower than the surfaces of the gates such that the sidewalls of the gates are partially exposed. A plurality of spacers is further formed on the exposed sidewalls of the gates. Using the gates and the spacers as masks, the first dielectric layer is anisotropically etched until the lightly doped regions are partially exposed. Using the gate and the spacer as masks, a plurality of heavily doped regions is formed in the lightly doped region and in the substrate. A second dielectric layer is formed covering the gates. The second dielectric is then defined to form a self-aligned contact window.

Abstract: A method for fabricating a shallow trench isolation structure is described, in which a pad oxide layer, a silicon oxy-nitride layer and the silicon nitride layer are sequentially formed on the substrate. Photolithography and etching are further conducted to form a trench in the substrate. A liner oxide layer is then formed on the exposed substrate surface in the trench, followed by removing portions of the silicon nitride layer and the silicon oxy-nitride layer by wet etching. After this, the trench is filled with an oxide material d the excessive oxide material is removed by using the silicon nitride layer as barrier layer. The remaining silicon nitride layer and the silicon oxy-nitride layer are further removed to complete the fabrication of a shallow trench isolation structure.