Abstract: Liquid chemical delivery systems are provided which include a liquid chemical storage canister, a pressurized gas source that feeds a pressurized gas into the storage canister, a vaporizer that may be used to vaporize the liquid chemical supplied from the storage canister, a delivery line that connects the storage canister to the vaporizer, a liquid mass flow controller that controls the flow rate of the liquid chemical through the delivery line, a reaction chamber that is connected to the vaporizer, and a liquid chemical recycling element that collects at least some of the chemical flowing through the system during periods when the liquid chemical delivery system is isolated from the reaction chamber.

Abstract: A capacitor including a dielectric structure, a lower electrode may be formed on a substrate. The dielectric structure may be formed on the lower electrode, and may include a first thin film, which may improve a morphology of the dielectric structure, and a second thin film, which may have at least one of an EOT larger than that of the first thin film and a dielectric constant higher than that of the first thin film. An upper electrode may be formed on the dielectric structure, and the dielectric structure may have an improved morphology and/or a higher dielectric constant.

Abstract: A method of manufacturing a semiconductor device can include forming a tunnel oxide layer on a substrate, forming a floating gate on the tunnel oxide layer and forming a dielectric layer pattern on the floating gate using an ALD process. The dielectric layer pattern can include a metal precursor that includes zirconium and an oxidant. A control gate can be formed on the dielectric layer pattern. The semiconductor device can include the dielectric layer pattern provided herein.

Abstract: A method of fabricating a nonvolatile memory device includes forming a charge tunneling layer on a semiconductor substrate, forming a charge trapping layer on the charge tunneling layer, forming a first charge blocking layer on the charge trapping layer by supplying a metal source gas and a first oxidizing gas onto the charge trapping layer, forming a second charge blocking layer on the first charge blocking layer by supplying a metal source gas and a second oxidizing gas onto the first charge blocking layer, wherein the second oxidizing gas has a higher oxidizing power as compared to the first oxidizing gas, and forming a gate electrode layer on the second charge blocking layer.

Abstract: A method of fabricating a nonvolatile memory device includes forming a charge tunneling layer on a semiconductor substrate, forming a charge trapping layer on the charge tunneling layer, forming a charge blocking layer on the charge trapping layer by supplying sequentially a metal source gas and an oxidizing gas onto the charge trapping layer, such that a supplying time of the oxidizing gas is form about 0.1 second to about 1.0 second, and forming a gate electrode layer on the charge blocking layer.

Abstract: A method of manufacturing a non-volatie memory device includes forming a tunnel insulating layer on a substrate, forming a conductive pattern on the tunnel insulating layer, forming a lower dielectric layer on the conductive pattern, performing a first heat treatment process to density the lower dielectric layer, and forming a middle dielectric layer having an energy band gap smaller than that of the lower dielectric layer on the first heat-treated lower dielectric layer. The method further includes forming an upper dielectric layer including a material substantially identical to that of the lower dielectric layer on the middle dielectric layer, performing a second heat treatment process to densify the middle dielectric layer and the upper dielectric layer and forming a conductive layer on the second heat-treated upper dielectric layer.

Abstract: A method of manufacturing a non-volatile memory device includes forming a tunnel isolation layer forming a tunnel isolation layer on a substrate, forming a conductive pattern on the tunnel isolation layer, forming a lower silicon oxide layer on the conductive pattern, treating a surface portion of the lower silicon oxide layer with a nitridation treatment to form a first silicon oxynitride layer on the lower silicon oxide layer, forming a metal oxide layer on the first silicon oxynitride layer, forming an upper silicon oxide layer on the metal oxide layer, and forming a conductive layer on the upper silicon oxide layer.

Abstract: A method of forming a flash memory device can include forming a tunneling oxide film on a semiconductor substrate, forming a charge storing layer on the tunneling oxide film, forming a first blocking oxide film on the charge storing layer at a first temperature, forming a second blocking oxide film on the first blocking oxide film at a second temperature higher than the first temperature, and forming a gate electrode on the second blocking oxide film.

Abstract: In a method of manufacturing a non-volatile memory device, a tunnel insulating layer may be formed on a channel region of a substrate. A charge trapping layer including silicon nitride may be formed on the tunnel insulating layer to trap electrons from the channel region. A heat treatment may be performed using a first gas including nitrogen and a second gas including oxygen to remove defect sites in the charge trapping layer and to densify the charge trapping layer. A blocking layer may be formed on the heat-treated charge trapping layer, and a conductive layer may then formed on the blocking layer. The blocking layer, the conductive layer, the heat-treated charge trapping layer and the tunnel insulating layer may be patterned to form a gate structure on the channel region. Accordingly, data retention performance and/or reliability of a non-volatile memory device including the gate structure may be improved.

Abstract: In a non-volatile memory device and a method of manufacturing the non-volatile memory device, a tunnel insulating layer, a charge trapping layer, a dielectric layer and a conductive layer may be sequentially formed on a channel region of a substrate. The conductive layer may be patterned to form a gate electrode and spacers may be formed on sidewalls of the gate electrode. A dielectric layer pattern, a charge trapping layer pattern, and a tunnel insulating layer pattern may be formed on the channel region by an anisotropic etching process using the spacers as an etch mask. Sidewalls of the charge trapping layer pattern may be removed by an isotropic etching process to reduce the width thereof. Thus, the likelihood of lateral diffusion of electrons may be reduced or prevented in the charge trapping layer pattern and high temperature stress characteristics of the non-volatile memory device may be improved.

Abstract: Example embodiments of the present invention disclose a non-volatile semiconductor memory device, which may include a dielectric layer having an enhanced dielectric constant. A tunnel oxide layer pattern and a floating gate may be sequentially formed on a substrate. A dielectric layer pattern including metal oxide doped with Group III transition metals may be formed on the floating gate using a pulsed laser deposition process. The dielectric layer pattern having an increased dielectric constant may be formed of metal oxide doped with a transition metal such as scandium, yttrium, or lanthanum.

Abstract: A thin film structure and a capacitor using the film structure and methods for forming the same. The thin film structure may include a first film formed on a substrate using a first reactant and an oxidant for oxidizing the first reactant. A second film may be formed on the first film to suppress crystallization of the first film. A capacitor may include a dielectric layer, which may further include the first thin film and the second thin film.

Abstract: A method of fabricating a floating trap type nonvolatile memory device includes forming a cell gate insulating layer on a semiconductor substrate, the cell gate insulating layer being comprised of a lower insulating layer, a charge storage layer and an upper insulating layer sequentially stacked; thermally annealing the cell gate insulating Layer at a temperature of approximately 810° C. to approximately 1370° C.; and forming a gate electrode on the thermally annealed cell gate insulating layer.

Abstract: A method of forming a dielectric film composed of metal oxide under an atmosphere of activated vapor containing oxygen. In the method of forming the dielectric film, a metal oxide film is formed on a semiconductor substrate using a metal organic precursor and O2 gas while the semiconductor substrate is exposed under activated vapor atmosphere containing oxygen, and then, the metal oxide film is annealed while the semiconductor substrate is exposed under activated vapor containing oxygen. The annealing may take place in situ with the formation of the metal oxide film, at the same or substantially the same temperature as the metal oxide forming, and/or at least one of a different pressure, oxygen concentration, or oxygen flow rate as the metal oxide forming.

Abstract: Disclosed are a method for cleaning a deposition chamber by removing attached metal oxides, and a deposition apparatus for performing in situ cleaning. A first gas and a second gas are provided into the deposition chamber. The first gas is reacted with metal included in the metal oxide to generate reacting residues. The second gas then decomposes the reacting residues, and the decomposed residues are exhausted out of the chamber. Thus, this cleaning process can be rapidly accomplished while the deposition chamber is not opened or separated from a deposition apparatus.

Abstract: A method of fabricating a floating trap type nonvolatile memory device is provided. The method includes forming a cell gate insulating layer on a semiconductor substrate, the cell gate insulating layer being comprised of a lower insulating layer, a charge storage layer and an upper insulating layer sequentially stacked; thermally annealing a resultant substrate including the cell gate insulating layer in a temperature range of 810-100° C.; and forming a gate electrode on the thermally annealed cell gate insulating layer.

Abstract: Embodiments of the present invention provide methods of manufacturing memory devices including forming floating gate patterns on a semiconductor substrate having active regions thereon, wherein the floating gate patterns cover the active regions and are spaced apart from the active regions; forming an inter-gate dielectric layer on the semiconductor substrate having the floating gate patterns by alternately stacking a zirconium oxide layer and an aluminum oxide layer at least once, wherein the inter-gate dielectric layer is formed by a deposition process using O3 gas as a reactive gas; forming a control gate layer on the inter-gate dielectric layer; and forming a control gate, an inter-gate dielectric layer pattern and a floating gate by sequentially patterning the control gate layer, the inter-gate dielectric layer and the floating gate pattern, wherein the inter-gate dielectric layer pattern and the control gate are sequentially stacked across the active regions, and the floating gate is formed between the

Abstract: Multi-layered structures formed using atomic-layer deposition processes include multiple metal oxide layers wherein the metal oxide layers are formed without the presence of interlayer oxide layers and may include different metal oxide compositions.

Abstract: A semiconductor device and/or gate structure having a composite dielectric layer and methods of manufacturing the same is provided. In the semiconductor device, gate structure, and methods provided, a first conductive layer may be formed on a substrate. A native oxide layer formed on the first conductive layer may be removed. A surface of the first conductive layer may be nitrided so that the surface may be altered into a nitride layer. A composite dielectric layer including the first and/or second dielectric layers may be formed on the nitride layer. A second conductive layer may be formed on the composite dielectric layer. The first dielectric layer may include a material having a higher dielectric constant. The second dielectric layer may be capable of suppressing crystallization of the first dielectric layer.

Abstract: A method of manufacturing a semiconductor device comprises forming a lower electrode on a substrate using a titanium chloride pulsed deposition (TPD) process, forming a high-k dielectric layer on the lower electrode, and forming an upper electrode on the dielectric layer using a TPD process. The method further comprises forming a reaction barrier layer between the upper or lower electrode and the dielectric layer using an atomic layer deposition (ALD) process. The upper electrode is preferably formed with a processing temperature between 350 and 500° C., and the dielectric layer preferably comprises zirconium oxide.