Abstract: A semiconductor device with a damascene wiring structure which can prevent short-circuits between a seal ring and a wiring line or electrode pad. The upper layer barrier layer made from a conductive barrier material film is formed on the interlayer insulating film groove sidewall of the semiconductor device, an upper layer seal ring wiring line with the thickness of approximately 10 micrometers for instance made from a wiring material film is embedded in a groove, and a plurality of isolated pockets of insulators are formed to be disbursed in the upper layer seal ring wiring line. These isolated pockets of insulators formed using the interlayer insulating film which forms the aforementioned damascene wiring line. Furthermore, a first upper layer groove wiring line and a second upper layer groove wiring line are formed in the element forming region, and an upper layer barrier layer is formed on the outside perimeter.

Abstract: Disclosed herein are slurry compositions for use in CMP(chemical mechanical polishing) process of metal wiring in manufacturing semiconductor devices, comprising a peroxide, an inorganic acid, a propylenediaminetetraacetate(PDTA)-metal complex, a carboxylic acid, a metal oxide powder, and de-ionized water, wherein the PDTA-metal complex plays a major role in improving overall polishing performance and reproducibility thereof by preventing abraded tungsten oxide from readhesion onto the polished surface, as well as in improving the dispersion stability of the slurry composition.

Abstract: A test pattern and a method of controlling a CMP using the same are provided. The test pattern is disposed on a monitoring region of a semiconductor substrate having a main region and a monitoring region. The test pattern includes a planar region and a pattern region. The method comprises setting a correlation between a step difference of a test pattern and an etched thickness of a main pattern, then applying the CMP to a semiconductor substrate having the test pattern and the main pattern for a predetermined time. The step difference of the test pattern is measured and the etched thickness of the main pattern, which corresponds to the step difference of the test pattern, is determined from the correlation. A polishing time is corrected by comparing the determined etched thickness of the main pattern with a reference value, and the corrected polishing time is applied to a subsequent lot or subsequent substrate.

Abstract: A CMP oxide slurry includes an aqueous solution containing abrasive particles and two or more different passivation agents. Preferably, the aqueous solution is made up of deionized water, and the abrasive particles are a metal oxide selected from the group consisting of ceria, silica, alumina, titania, zirconia and germania. Also, a first passivation agent may be an anionic, cationic or nonionic surfactant, and a second passivation agent may be a phthalic acid and its salts. In one example, the first passivation agent is poly-vinyl sulfonic acid, and the second passivation agent is potassium hydrogen phthalate. The slurry exhibits a high oxide to silicon nitride removal selectivity.

Abstract: Slurries for chemical mechanical polishing (CMP) are provided including a high planarity slurry and high selectivity ratio slurry. A high planarity slurry includes at least one kind of metal oxide abrasive particle and an anionic polymer passivation agent having a first concentration. A high selectivity ratio slurry includes at least one kind of the metal oxide abrasive particle, the passivation agent in a second concentration that is less than the first concentration of the passivation agent for the high planarity slurry, one of a quaternary amine and the salt thereof, and a pH control agent. The high selectivity ratio slurry has a pH in a range of about over an isoelectric point of a polishing target layer and less than an isoelectric point of a polishing stopper. In addition, a CMP method using the CMP slurries having high planarity and high selectivity ratio is provided.

Abstract: A test pattern and a method of controlling a CMP using the same are provided. The test pattern is disposed on a monitoring region of a semiconductor substrate having a main region and a monitoring region. The test pattern includes a planar region and a pattern region. The method comprises setting a correlation between a step difference of a test pattern and an etched thickness of a main pattern, then applying the CMP to a semiconductor substrate having the test pattern and the main pattern for a predetermined time. The step difference of the test pattern is measured and the etched thickness of the main pattern, which corresponds to the step difference of the test pattern, is determined from the correlation. A polishing time is corrected by comparing the determined etched thickness of the main pattern with a reference value, and the corrected polishing time is applied to a subsequent lot or subsequent substrate.

Abstract: A polishing slurry including an abrasive, deionized water, a pH controlling agent, and polyethylene imine, can control the removal rates of a silicon oxide layer and a silicon nitride layer which are simultaneously exposed during chemical mechanical polishing (CMP) of a conductive layer. A relative ratio of the removal rate of the silicon oxide layer to that of the silicon nitride layer can be controlled by controlling an amount of the choline derivative.

Abstract: Disclosed herein are slurry compositions for use in CMP (chemical mechanical polishing) process of metal wiring in manufacturing semiconductor devices, comprising a peroxide, an inorganic acid, a propylenediaminetetraacetate (PDTA)-metal complex, a carboxylic acid, a metal oxide powder, and de-ionized water, wherein the PDTA-metal complex plays a major role in improving overall polishing performance and reproducibility thereof by preventing abraded tungsten oxide from readhesion onto the polished surface, as well as in improving the dispersion stability of the slurry composition.

Abstract: A polishing slurry including an abrasive, deionized water, a pH controlling agent, and polyethylene imine, can control the removal rates of a silicon oxide layer and a silicon nitride layer which are simultaneously exposed during chemical mechanical polishing (CMP) of a conductive layer. A relative ratio of the removal rate of the silicon oxide layer to that of the silicon nitride layer can be controlled by controlling an amount of the choline derivative.

Abstract: A method of fabricating a contact pad of a semiconductor device is disclosed. The method includes forming a stopping layer over the semiconductor substrate. An interdielectric layer is formed over the stopping layer, and the interdielectric layer is planarized to expose at least a gate upper dielectric layer by using a material which exhibits a high-polishing selectivity with respect to the interdielectric layer. The interdielectric layer is etched in a region in which a contact pad will be formed on the semiconductor substrate. A conductive material is deposited on the semiconductor substrate. Finally, planarizing is carried out using a material which exhibits a high-polishing selectivity of the upper dielectric layer with respect to the conductive material.

Abstract: A slurry composition useful for chemical mechanical polishing of the surface of a material layer, e.g., a silicon oxide layer, is disclosed. A first material surface which is exposed to the slurry exhibits hydrophilicity, while a second material layer, e.g., a polysilicon layer, the surface of which is also exposed to the slurry, exhibits hydrophobicity, and accordingly acts as a polishing stopping layer. The slurry composition consists essentially of water, abrasive grains, and a polymer additive having both hydrophilic and hydrophobic functional groups.

Abstract: A method for forming a filling film having an even surface and a method for forming a trench isolation using a polishing process. After a substrate having stepped portions thereon is provided, a film is formed on the substrate to cover the stepped portions of the substrate. The edge of the stepped portion of the film is processed to have a round shape, and then the film including the round shaped edge portion is chemical-mechanically polished to form the filling film having an even surface. Before the film is polished, the film to be polished is processed to have the round shape, thereby increasing the polishing rate of the film.

Abstract: A method is provided for forming a metal interconnection using a plating process, which can improve the throughput and reliability of semiconductor devices by decreasing the required polishing in a chemical mechanical polishing process. A semiconductor device manufactured by this method is also provided. In the method of forming a metal interconnection, a recess region is formed in a portion of an insulation layer formed over a substrate, i.e., where a metal interconnection layer will be formed. A diffusion prevention layer is formed over the substrate, the insulation layer, and the recess region. Then, a metal seed layer is formed over the diffusion prevention layer only in the recess region using a chemical mechanical polishing process or an etch back process. A conductive plating layer is then formed on the metal seed layer only in the recess region. Thereafter, surface planarization is performed to form a metal interconnection layer in the recess region.

Abstract: A test pattern and a method of controlling a CMP using the same are provided. The test pattern is disposed on a monitoring region of a semiconductor substrate having a main region and a monitoring region. The test pattern includes a planar region and a pattern region. The method comprises setting a correlation between a step difference of a test pattern and an etched thickness of a main pattern, then applying the CMP to a semiconductor substrate having the test pattern and the main pattern for a predetermined time. The step difference of the test pattern is measured and the etched thickness of the main pattern, which corresponds to the step difference of the test pattern, is determined from the correlation. A polishing time is corrected by comparing the determined etched thickness of the main pattern with a reference value, and the corrected polishing time is applied to a subsequent lot or subsequent substrate.

Abstract: A slurry composition useful for chemical mechanical polishing of the surface of a material layer, e.g., a silicon oxide layer, is disclosed. A first material surface which is exposed to the slurry exhibits hydrophilicity, while a second material layer, e.g., a polysilicon layer, the surface of which is also exposed to the slurry, exhibits hydrophobicity, and accordingly acts as a polishing stopping layer. The slurry composition consists essentially of water, abrasive grains, and a polymer additive having both hydrophilic and hydrophobic functional groups.

Abstract: Slurries for chemical mechanical polishing (CMP) are provided including a high planarity slurry and high selectivity ratio slurry. A high planarity slurry includes at least one kind of metal oxide abrasive particle and an anionic polymer passivation agent having a first concentration. A high selectivity ratio slurry includes at least one kind of the metal oxide abrasive particle, the passivation agent in a second concentration that is less than the first concentration of the passivation agent for the high planarity slurry, one of a quaternary amine and the salt thereof, and a pH control agent. The high selectivity ratio slurry has a pH in a range of about over an isoelectric point of a polishing target layer and less than an isoelectric point of a polishing stopper. In addition, a CMP method using the CMP slurries having high planarity and high selectivity ratio is provided.

Abstract: A method is provided for forming a metal interconnection using a plating process, which can improve the throughput and reliability of semiconductor devices by decreasing the required polishing in a chemical mechanical polishing process. A semiconductor device manufactured by this method is also provided. In the method of forming a metal interconnection, a recess region is formed in a portion of an insulation layer formed over a substrate, i.e., where a metal interconnection layer will be formed. A diffusion prevention layer is formed over the substrate, the insulation layer, and the recess region. Then, a metal seed layer is formed over the diffusion prevention layer only in the recess region using a chemical mechanical polishing process or an etch back process. A conductive plating layer is then formed on the metal seed layer only in the recess region. Thereafter, surface polarization is performed to form a metal interconnection layer in the recess region.

Abstract: A CMP oxide slurry includes an aqueous solution containing abrasive particles and two or more different passivation agents. Preferably, the aqueous solution is made up of deionized water, and the abrasive particles are a metal oxide selected from the group consisting of ceria, silica, alumina, titania, zirconia and germania. Also, a first passivation agent may be an anionic, cationic or nonionic surfactant, and a second passivation agent may be a phthalic acid and its salts. In one example, the first passivation agent is poly-vinyl sulfonic acid, and the second passivation agent is potassium hydrogen phthalate. The slurry exhibits a high oxide to silicon nitride removal selectivity.

Abstract: A gate electrode conductive layer is formed on an active region that is recessed relative to field oxide layers so as to define a damascene structure. The gate electrode conductive layer is formed on the active region but is not formed on a field region so that the thickness of an interlayer insulation layer deposited in a succeeding process is reduced, thereby reducing or preventing voids within the interlayer insulation layer. A polysilicon is formed on the bottom of the active region by selective epitaxial growth, thereby minimizing the influence of micro scratches, pits or stringers occurring on the bottom of the active region.

Abstract: An insulating layer can be formed on first and second adjacent regions of an integrated circuit having a first step difference therebetween, the first and second regions having first and second respective etch rates associated therewith. A recess can be formed in the insulating layer on the second region having a second step difference with the first region that is less than the first step difference to provide a portion of the insulating layer between the first and second adjacent regions having a third step difference with the first region that is greater than the second step difference. A width of the portion is selected based on a difference between the first and second etch rates.