Abstract: There is provided an additive for secondary battery electrolyte, containing aluminum silicate. The aluminum silicate has a particle size of 200 nm to 20 ?m. The aluminum silicate has a mass ratio of 60 to 70 wt % of oxygen (O), 0.1 to 2.0 wt % of aluminum (Al), and 25 to 35 wt % of silicon (Si). The aluminum silicate has a surface area of 50 to 1,000 m2/g. The aluminum silicate has a pore size of 0.1 to 20 nm.

Abstract: There is provided an additive, containing magnesium silicate, for a secondary battery electrolyte and a preparation method therefor. The magnesium silicate has a mass ratio of 50 to 70 wt % of oxygen (O), 5 to 20 wt % of magnesium (Al), and 15 to 35 wt % of silicon (Si). The magnesium silicate has a surface area of 50 to 500 m2/g. The magnesium silicate has a pore size of 0.1 to 20 nm.

Abstract: A substrate processing apparatus includes a chamber providing a space in which a substrate is processed, a first substrate support within the chamber and configured to support the substrate when the substrate is loaded into chamber, a second substrate support within the chamber and configured to support the substrate in a height greater than the height in which the first substrate supports the substrate, a first supply port through which a supercritical fluid is supplied to a first space under the substrate of a chamber space, a second supply port through which the supercritical fluid is supplied to a second space above the substrate of the chamber space, and an exhaust port through which the supercritical fluid is exhausted from the chamber.

Abstract: A substrate processing apparatus includes a chamber providing a space in which a substrate is processed, a first substrate support within the chamber and configured to support the substrate when the substrate is loaded into chamber, a second substrate support within the chamber and configured to support the substrate in a height greater than the height in which the first substrate supports the substrate, a first supply port through which a supercritical fluid is supplied to a first space under the substrate of a chamber space, a second supply port through which the supercritical fluid is supplied to a second space above the substrate of the chamber space, and an exhaust port through which the supercritical fluid is exhausted from the chamber.

Abstract: A substrate processing apparatus includes a chamber providing a space in which a substrate is processed, a first substrate support within the chamber and configured to support the substrate when the substrate is loaded into chamber, a second substrate support within the chamber and configured to support the substrate in a height greater than the height in which the first substrate supports the substrate, a first supply port through which a supercritical fluid is supplied to a first space under the substrate of a chamber space, a second supply port through which the supercritical fluid is supplied to a second space above the substrate of the chamber space, and an exhaust port through which the supercritical fluid is exhausted from the chamber.

Abstract: A source supplier includes a source reservoir that contains a liquefied source fluid for a supercritical process, a vaporizer that vaporizes the liquefied source fluid into a gaseous source fluid under high pressure, a purifier that removes organic impurities and moistures from the gaseous source fluid and an analyzer connected to the purifier that analyzes an impurity fraction and a moisture fraction in the gaseous source fluid. Moisture and organic impurities are removed from the source fluid to reduce the moisture concentration of the supercritical fluid in the supercritical process.

Abstract: A substrate processing apparatus includes a chamber providing a space in which a substrate is processed, a first substrate support within the chamber and configured to support the substrate when the substrate is loaded into chamber, a second substrate support within the chamber and configured to support the substrate in a height greater than the height in which the first substrate supports the substrate, a first supply port through which a supercritical fluid is supplied to a first space under the substrate of a chamber space, a second supply port through which the supercritical fluid is supplied to a second space above the substrate of the chamber space, and an exhaust port through which the supercritical fluid is exhausted from the chamber.

Abstract: A source supplier includes a source reservoir that contains a liquefied source fluid for a supercritical process, a vaporizer that vaporizes the liquefied source fluid into a gaseous source fluid under high pressure, a purifier that removes organic impurities and moistures from the gaseous source fluid and an analyzer connected to the purifier that analyzes an impurity fraction and a moisture fraction in the gaseous source fluid. Moisture and organic impurities are removed from the source fluid to reduce the moisture concentration of the supercritical fluid in the supercritical process.

Abstract: A wet etching nozzle, semiconductor manufacturing equipment including the same, and a wet etching method using the same are provided. The wet etching nozzle includes a first supply pipe configured to supply a first solution, for etching a partial area of an etched layer, to a substrate including the etched layer; a first suction pipe configured to suck the first solution from the substrate; a second supply pipe configured to supply a second solution for cleaning the partial area of the etched layer; and a second suction pipe configured to suck the second solution from the substrate.

Abstract: A method of removing a photoresist may include permeating supercritical carbon dioxide into the photoresist on a substrate having a conductive structure including a metal. The photoresist permeating the supercritical carbon dioxide may be easily removable. The photoresist permeating the supercritical carbon dioxide may be removed using a photoresist cleaning solution from the substrate. The photoresist cleaning solution may include an alkanolamine solution of about 8 percent by weight to about 20 percent by weight, a polar organic solution of about 25 percent by weight to about 40 percent by weight, a reducing agent of about 0.5 percent by weight to about 3 percent by weight with the remainder being water. The photoresist may be easily removed without damaging the conductive structure in a plasma process.

Abstract: A method of manufacturing a nonvolatile semiconductor memory device may include forming a pad oxide layer pattern and a mask pattern on a semiconductor substrate, forming a trench within the semiconductor substrate with the mask pattern functioning as an etching mask, sequentially forming a first device isolation layer and a second device isolation layer that may fill the trench, forming an opening by removing the mask pattern to expose an upper surface of the pad oxide layer pattern and a sidewall of the second device isolation layer, and forming a floating gate forming region having a width wider than the opening by simultaneously removing the pad oxide layer pattern and a sidewall portion of the second device isolation layer exposed by the opening.

Abstract: A nonvolatile memory device and a method for fabricating the nonvolatile memory device are disclosed. The method comprises forming a device isolation pattern comprising a first opening and a second opening wider than the first opening, wherein the first opening is formed in the second opening; and forming a gate insulating layer on a first portion of an active region of the substrate, wherein the first opening exposes the first portion of the active region of the substrate. The method further comprises forming a first conductive layer in the first and second openings and on the gate insulating layer, partially etching the first conductive layer to form a U-shaped floating gate electrode, forming a gate interlayer insulating layer on the U-shaped floating gate electrode, forming a second conductive layer on the gate interlayer insulating layer and the device isolation pattern, and patterning the second conductive layer.

Abstract: A method of removing a photoresist may include permeating supercritical carbon dioxide into the photoresist on a substrate having a conductive structure including a metal. The photoresist permeating the supercritical carbon dioxide may be easily removable. The photoresist permeating the supercritical carbon dioxide may be removed using a photoresist cleaning solution from the substrate. The photoresist cleaning solution may include an alkanolamine solution of about 8 percent by weight to about 20 percent by weight, a polar organic solution of about 25 percent by weight to about 40 percent by weight, a reducing agent of about 0.5 percent by weight to about 3 percent by weight with the remainder being water. The photoresist may be easily removed without damaging the conductive structure in a plasma process.

Abstract: A method for fabricating a semiconductor device is disclosed. The method includes forming an etch stop layer on a substrate, forming a mold layer on the substrate, and forming an opening exposing the substrate by patterning the mold layer and the etch stop layer, wherein the opening includes a lower portion defined by the etch stop layer and a middle portion. The method further includes enlarging the lower portion by etching a side portion of the etch stop layer exposed by the opening using an etching solution including sulfuric acid and water; and forming a lower electrode on an inner surface of the opening including the enlarged lower portion, wherein, after enlarging the lower portion, a width of the lower portion is greater than a width of the middle portion.

Abstract: A cleaning method for a semiconductor substrate including placing the semiconductor substrate into a cleaning chamber and injecting ozone gas (O3) into the cleaning chamber. This process operates to cleanse the semiconductor substrate without corrosion or etching of the semiconductor substrate; even when the substrate has metal layer made of tungsten.

Abstract: A method of manufacturing a nonvolatile semiconductor memory device may include forming a pad oxide layer pattern and a mask pattern on a semiconductor substrate, forming a trench within the semiconductor substrate with the mask pattern functioning as an etching mask, sequentially forming a first device isolation layer and a second device isolation layer that may fill the trench, forming an opening by removing the mask pattern to expose an upper surface of the pad oxide layer pattern and a sidewall of the second device isolation layer, and forming a floating gate forming region having a width wider than the opening by simultaneously removing the pad oxide layer pattern and a sidewall portion of the second device isolation layer exposed by the opening.

Abstract: A method for cleaning a semiconductor substrate forming device isolation layers in a predetermined region of a semiconductor substrate to define active regions; etching predetermined areas of the active regions to form a recess channel region and such that sidewalls of the device isolation layers are exposed; and selectively etching a surface of the recess channel region using a predetermined cleaning solution to clean the semiconductor substrate where the recess channel region has been formed.

Abstract: A nonvolatile memory device and a method for fabricating the nonvolatile memory device are disclosed. The method comprises forming a device isolation pattern comprising a first opening and a second opening wider than the first opening, wherein the first opening is formed in the second opening; and forming a gate insulating layer on a first portion of an active region of the substrate, wherein the first opening exposes the first portion of the active region of the substrate. The method further comprises forming a first conductive layer in the first and second openings and on the gate insulating layer, partially etching the first conductive layer to form a U-shaped floating gate electrode, forming a gate interlayer insulating layer on the U-shaped floating gate electrode, forming a second conductive layer on the gate interlayer insulating layer and the device isolation pattern, and patterning the second conductive layer.

Abstract: A method for cleaning a semiconductor substrate forming device isolation layers in a predetermined region of a semiconductor substrate to define active regions; etching predetermined areas of the active regions to form a recess channel region and such that sidewalls of the device isolation layers are exposed; and selectively etching a surface of the recess channel region using a predetermined cleaning solution to clean the semiconductor substrate where the recess channel region has been formed.

Abstract: A cleaning method for a semiconductor substrate including placing the semiconductor substrate into a cleaning chamber and injecting ozone gas (O3) into the cleaning chamber. This process operates to cleanse the semiconductor substrate without corrosion or etching of the semiconductor substrate; even when the substrate has metal layer made of tungsten.