Abstract: Improved methods are disclosed for catalyst-assisted atomic layer deposition (ALD) to form a silicon dioxide layer having superior properties on a semiconductor substrate by using a first reactant component consisting of a silicon compound having at least two silicon atoms, or using a tertiary aliphatic amine as the catalyst component, or both in combination, together with related purging methods and sequencing.

Abstract: Improved methods are disclosed for catalyst-assisted atomic layer deposition (ALD) to form a silicon dioxide layer having superior properties on a semiconductor substrate by using a first reactant component consisting of a silicon compound having at least two silicon atoms, or using a tertiary aliphatic amine as the catalyst component, or both in combination, together with related purging methods and sequencing.

Abstract: Provided is a method of forming a fine pattern, in which a silicon oxide layer is formed on a photoresist pattern and dry etching is performed on the resultant structure. According to the method, a photoresist pattern is formed on a material layer on which a fine pattern is to be formed, a silicon oxide layer is conformally deposited on the photoresist pattern without damaging the photoresist pattern, and dry etching is performed on a lower layer. During the dry etching, spacers are formed along the sidewalls of the photoresist pattern, and then, a polymer layer is formed on the photoresist pattern. Accordingly, it is possible to prevent the thinning of the photoresist pattern so that a desired pattern can be obtained, and further, to prevent striation or wiggling from occurring on the patterned material layer.

Abstract: There are provided methods of fabricating a metal silicate layer on a semiconductor substrate using an atomic layer deposition technique. The methods include performing a metal silicate layer formation cycle at least one time in order to form a metal silicate layer having a desired thickness. The metal silicate layer formation cycle includes an operation of repeatedly performing a metal oxide layer formation cycle K times and an operation of repeatedly performing a silicon oxide layer formation cycle Q times. K and Q are integers ranging from 1 to 10 respectively. The metal oxide layer formation cycle includes the steps of supplying a metal source gas to a reactor containing the substrate, exhausting the metal source gas remaining in a reactor to clean the inside of the reactor, and then supplying an oxide gas into the reactor.

Abstract: Methods of fabricating high-k dielectric layers having reduced impurities for use in semiconductor applications are disclosed. The methods include the steps of: forming a stacked dielectric layer having a first dielectric layer and a second dielectric layer formed on a semiconductor substrate using an ALD method, in combination with a post-treatment step performed to the stacked dielectric layer. The steps of forming the stacked dielectric layer and performing the post-treatment are repeated at least once, thereby fabricating the high-k dielectric layer.

Abstract: A method of forming a thin film with a low hydrogen contents is provided by positioning a substrate inside a processing chamber, and supplying reacting materials into the chamber, chemisorbing a portion of the reacting materials onto the substrate. Then, a nitrogen (N2) remote plasma treatment is performed to reduce the hydrogen content of thin film layer formed by chemisorption of the reacting materials on the substrate. Accordingly, a thin film is formed having a low hydrogen content, since the hydrogen bonds in the thin film layer formed by chemisorption of the reacting materials are removed.

Abstract: Provided are a semiconductor device having an etch stopper formed of a nitride film by low temperature atomic layer deposition which can prevent damage to a semiconductor substrate and a method for fabricating the semiconductor device. Damage to the semiconductor substrate under the etch stopper composed of a second nitride film can be prevented by forming a first nitride film using high temperature LPCVD on the semiconductor substrate, forming the etch stopper including the second nitride film by low temperature ALD on the first nitride film, and removing the second nitride film by dry etching, thus taking advantage of the different etch selectivities of the first nitride film and the second nitride film.

Abstract: Provided are a semiconductor device having an etch stopper formed of a nitride film by low temperature atomic layer deposition which can prevent damage to a semiconductor substrate and a method for fabricating the semiconductor device. Damage to the semiconductor substrate under the etch stopper composed of a second nitride film can be prevented by forming a first nitride film using high temperature LPCVD on the semiconductor substrate, forming the etch stopper including the second nitride film by low temperature ALD on the first nitride film, and removing the second nitride film by dry etching, thus taking advantage of the different etch selectivities of the first nitride film and the second nitride film.

Abstract: An information storage medium that contains audio mixing information, which includes a multiplicity of audio channel components containing audio data, and the mixing information is used to mix the audio channel components and additional channel components to be added. Accordingly, it is possible to mix different channel components from different audio streams and reproduce an audio stream using an apparatus and/or a method.

Abstract: Provided are a semiconductor device having an etch stopper formed of a nitride film by low temperature atomic layer deposition which can prevent damage to a semiconductor substrate and a method for fabricating the semiconductor device. Damage to the semiconductor substrate under the etch stopper composed of a second nitride film can be prevented by forming a first nitride film using high temperature LPCVD on the semiconductor substrate, forming the etch stopper including the second nitride film by low temperature ALD on the first nitride film, and removing the second nitride film by dry etching, thus taking advantage of the different etch selectivities of the first nitride film and the second nitride film.

Abstract: Provided is a method of manufacturing a semiconductor device with an LDD structure using a decreased number of mask-patterning processes using photolithography. The method includes forming an LDD region by implanting low-concentration impurity ions into a semiconductor substrate using a gate electrode, the sidewall of which are exposed, as an ion implantation mask. Then, to form a source/drain region, high-concentration impurity ions are implanted into the semiconductor substrate using a sacrificial masking layer, which covers the top surface and sidewalls of the gate electrode and the top surface of the semiconductor substrate to a uniform thickness, as an ion implantation mask. Implantation of the high-concentration impurity ions may be performed before or after implantation of the low-concentration impurity ions. When a CMOS transistor is formed, additional masks to be used as ion implantation masks are not required for implanting high-concentration impurity ions to form source/drain regions.

Abstract: A method is provided for forming a silicon dioxide film using atomic layer deposition (ALD), wherein a halogen- or NCO-substituted siloxane is used as a Si source. The method includes feeding a substituted siloxane as a first reactant onto a substrate to form a chemisorbed layer of the first reactant, and thereafter feeding a compound consisting of oxygen and hydrogen as a second reactant onto the chemisorbed layer to form the desired silicon dioxide film.

Abstract: Provided is an atomic layer deposition (ALD) apparatus in which the generation of powders is suppressed by providing a largely dedicated exhaust path for each of the reactants utilized in the ALD process. The ALD apparatus includes a reactor in which an ALD process is performed on a wafer using two or more types of reactants; reactant suppliers, each of which alternately supplies a different reactant to the reactor; and an exhaust path for each type of reactant so that the non-reacted portion of the reactants removed from the reaction chamber do not mix and react in the exhaust path.

Abstract: In an electrode line structure of a semiconductor device and a method for forming the same, the electrode line structure comprises a semiconductor substrate, and electrode lines, which are formed on the semiconductor substrate, and have an inclined end in the long axis direction. The electrode lines each include a first line unit, which substantially functions as an electrode line, a second line unit, which has an inclined end in the long axis direction and is separated from the first line unit by a predetermined distance, and an insulating plug, which is interposed between the first line unit and the second line unit and electrically insulates the first line unit from the second line unit.

Abstract: Provided are a semiconductor device having an etch stopper formed of a nitride film by low temperature atomic layer deposition which can prevent damage to a semiconductor substrate and a method for fabricating the semiconductor device. Damage to the semiconductor substrate under the etch stopper composed of a second nitride film can be prevented by forming a first nitride film using high temperature LPCVD on the semiconductor substrate, forming the etch stopper including the second nitride film by low temperature ALD on the first nitride film, and removing the second nitride film by dry etching, thus taking advantage of the different etch selectivities of the first nitride film and the second nitride film.

Abstract: Provided is a method of forming a fine pattern, in which a silicon oxide layer is formed on a photoresist pattern and dry etching is performed on the resultant structure. According to the method, a photoresist pattern is formed on a material layer on which a fine pattern is to be formed, a silicon oxide layer is conformally deposited on the photoresist pattern without damaging the photoresist pattern, and dry etching is performed on a lower layer. During the dry etching, spacers are formed along the sidewalls of the photoresist pattern, and then, a polymer layer is formed on the photoresist pattern. Accordingly, it is possible to prevent the thinning of the photoresist pattern so that a desired pattern can be obtained, and further, to prevent striation or wiggling from occurring on the patterned material layer.

Abstract: Improved methods are disclosed for catalyst-assisted atomic layer deposition (ALD) to form a silicon dioxide layer having superior properties on a semiconductor substrate by using a first reactant component consisting of a silicon compound having at least two silicon atoms, or using a tertiary aliphatic amine as the catalyst component, or both in combination, together with related purging methods and sequencing.

Abstract: A method of forming a thin film with a low hydrogen contents is provided by positioning a substrate inside a processing chamber, and supplying reacting materials into the chamber, chemisorbing a portion of the reacting materials onto the substrate. Then, a nitrogen (N2) remote plasma treatment is performed to reduce the hydrogen content of thin film layer formed by chemisorption of the reacting materials on the substrate. Accordingly, a thin film is formed having a low hydrogen content, since the hydrogen bonds in the thin film layer formed by chemisorption of the reacting materials are removed.