Abstract: In a method of forming a capacitor, a first mold layer pattern including a first insulating material may be formed on a substrate. The first mold layer pattern may have a trench. A supporting layer including a second insulating material may be formed in the trench. The second insulating material may have an etching selectivity with respect to the first insulating material. A second mold layer may be formed on the first mold layer pattern and the supporting layer pattern. A lower electrode may be formed through the second mold layer and the first mold layer pattern. The lower electrode may make contact with a sidewall of the supporting layer pattern. The first mold layer pattern and the second mold layer may be removed. A dielectric layer and an upper electrode may be formed on the lower electrode and the supporting layer pattern.

Abstract: The inventive concept provides methods of manufacturing three-dimensional semiconductor devices. In some embodiments, the methods include forming a stack structure including sacrificial layers and insulation layers, forming a trench penetrating the stack structure, forming a hydrophobic passivation element on the surfaces of the insulation layers that were exposed by the trench and selectively removing the sacrificial layers.

Abstract: A method of manufacturing a nonvolatile memory device having a three-dimensional memory device includes alternately stacking a plurality of first and second material layers having a different etching selectivity on a semiconductor substrate; forming an opening penetrating the plurality of first and second material layers; removing the first material layers exposed by the opening to form extended portions extending in a direction perpendicular to the semiconductor substrate from the opening; conformally forming a charge storage layer along a surface of the opening and the extended portions; and removing the charge storage layer formed on sidewalls of the second material layers to locally form the charge storage layer patterns in the extended portions.

Abstract: In a vertical-type non-volatile memory device, an insulation layer pattern is provided on a substrate, the insulation layer pattern having a linear shape. Single-crystalline semiconductor patterns are provided on the substrate to make contact with both sidewalls of the insulation layer pattern, the single-crystalline semiconductor patterns having a pillar shape that extends in a vertical direction relative to the substrate. A tunnel oxide layer is provided on the single-crystalline semiconductor pattern. A lower electrode layer pattern is provided on the tunnel oxide layer and on the substrate. A plurality of insulation interlayer patterns is provided on the lower electrode layer pattern, the insulation interlayer patterns being spaced apart from one another by a predetermined distance along the single-crystalline semiconductor pattern. A charge-trapping layer and a blocking dielectric layer are sequentially formed on the tunnel oxide layer between the insulation interlayer patterns.

Abstract: The inventive concept provides a wafer test method and a wafer test apparatus. The wafer test method can recognize the amount of residuals generated in a sidewall of the metal-containing layer pattern and the extent of corrosion of a sidewall of the metal-containing layer pattern using the measured electric resistance by supplying an electrolyte so that the electrolyte is in contact with a portion of the metal-containing layer pattern in a predetermined chip region and measuring an electric resistance between a first electrode which is electrically in contact with the other portion of the metal-containing layer pattern and a second electrode which is in contact with the electrolyte in the predetermined region. Thus, a wafer test method and a wafer test apparatus can be embodied by an in-line method without dividing a wafer into each chip.

Abstract: In a supercritical fluid method a supercritical fluid is supplied into a process chamber. The supercritical fluid is discharged from the process chamber as a supercritical fluid process proceeds. A concentration of a target material included in the supercritical fluid discharged from the process chamber is detected during the supercritical fluid process. An end point of the supercritical fluid process may be determined based on a detected concentration of the target material.

Abstract: In a method of forming a capacitor, a first mold layer pattern including a first insulating material may be formed on a substrate. The first mold layer pattern may have a trench. A supporting layer including a second insulating material may be formed in the trench. The second insulating material may have an etching selectivity with respect to the first insulating material. A second mold layer may be formed on the first mold layer pattern and the supporting layer pattern. A lower electrode may be formed through the second mold layer and the first mold layer pattern. The lower electrode may make contact with a sidewall of the supporting layer pattern. The first mold layer pattern and the second mold layer may be removed. A dielectric layer and an upper electrode may be formed on the lower electrode and the supporting layer pattern.

Abstract: Example embodiments relate to an apparatus for drying a substrate. The apparatus may include a housing including first barrier walls having a first height, a rotary chuck that is disposed within the housing and configured to rotate the substrate, a nozzle system that is disposed above the rotary chuck and configured to supply a fluid onto the substrate, a cleaning liquid supply unit supplying a cleaning liquid for cleaning the substrate to the nozzle system, and a drying liquid supply unit supplying a drying liquid for drying the substrate to the nozzle system.

Abstract: A method of forming a capacitor structure and manufacturing a semiconductor device, the method of forming a capacitor structure including sequentially forming a first mold layer, a supporting layer, a second mold layer, an anti-bowing layer, and a third mold layer on a substrate having a conductive region thereon; partially removing the third mold layer, the anti-bowing layer, the second mold layer, the supporting layer, and the first mold layer to form a first opening exposing the conductive region; forming a lower electrode on a sidewall and bottom of the first opening, the lower electrode being electrically connected to the conductive region; further removing the third mold layer, the anti-bowing layer, and the second mold layer; partially removing the supporting layer to form a supporting layer pattern; removing the first mold layer; and sequentially forming a dielectric layer and upper electrode on the lower electrode and the supporting layer pattern.

Abstract: Substrate treatment equipment includes a wet treatment apparatus for treating a substrate with a solution (liquid), a drying (treatment) apparatus discrete from the wet treatment apparatus and for drying the substrate using a supercritical fluid, and a transfer device. The substrate is extracted by the transfer device from the wet treatment apparatus after the substrate has been treated and the substrate is transferred by the device while wet to the dry treatment apparatus. To this end, various elements/methods may be used to keep the substrate wet or wet the substrate. In any case, the substrate is prevented from drying naturally, i.e., from air-drying, as the substrate is being transferred from the wet treatment apparatus to the drying apparatus. Thus, equipment and method prevent defects such as water spots and the leaning of fine structures on the substrate.

Abstract: In a method of forming a capacitor, a first mold layer pattern including a first insulating material may be formed on a substrate. The first mold layer pattern may have a trench. A supporting layer including a second insulating material may be formed in the trench. The second insulating material may have an etching selectivity with respect to the first insulating material. A second mold layer may be formed on the first mold layer pattern and the supporting layer pattern. A lower electrode may be formed through the second mold layer and the first mold layer pattern. The lower electrode may make contact with a sidewall of the supporting layer pattern. The first mold layer pattern and the second mold layer may be removed. A dielectric layer and an upper electrode may be formed on the lower electrode and the supporting layer pattern.

Abstract: Provided are nonvolatile memory devices with a three-dimensional structure and methods of fabricating the same. The nonvolatile memory device includes conductive patterns three-dimensionally arranged on a semiconductor substrate, semiconductor patterns that extend from the semiconductor substrate and intersect one-side walls of the conductive patterns, charge storage layers interposed between the semiconductor patterns and one-side walls of the conductive patterns, and seed layer patterns interposed between the charge storage layers and one-side walls of the conductive patterns.

Abstract: An insulation layer may be formed on an object having a contact region. The insulation layer may be partially etched to form an opening exposing the contact region. A material layer including silicon and oxygen may be formed on the exposed contact region. A metal layer may be formed on the material layer including silicon and oxygen. The material layer including silicon and oxygen may be reacted with the metal layer to form a metal oxide silicide layer at least on the contact region. A conductive layer may be formed on the metal oxide silicide layer to fill up the opening.

Abstract: Methods of forming nonvolatile memory devices include forming a stack of layers of different materials on a substrate. This stack includes a plurality of first layers of a first material and a plurality of second layers of a second material arranged in an alternating sequence of first and second layers. A selected first portion of the stack of layers is isotropically etched for a sufficient duration to define a first trench therein that exposes sidewalls of the alternating sequence of first and second layers. The sidewalls of each of the plurality of first layers are selectively etched relative to sidewalls of adjacent ones of the plurality of second layers. Another etching step is then performed to recess sidewalls of the plurality of second layers and thereby expose portions of upper surfaces of the plurality of first layers. These exposed portions of the upper surfaces of the plurality of first layers, which may act as word lines of a memory device, are displaced laterally relative to each other.

Abstract: Method of manufacturing semiconductor device are provided including forming an insulation layer having a pad on a substrate; forming an etch stop layer on the insulation layer and the pad; forming a mold structure having at least one mold layer on the etch stop layer; forming a first supporting layer on the mold structure; etching the first supporting layer and the mold structure to form a first opening exposing the etch stop layer; forming a spacer on a sidewall of the first opening; etching the etch stop layer using the spacer as an etching mask to form a second opening, different from the first opening, exposing a first portion of the pad having a first associated area; etching the etch stop layer using the spacer as an etching mask to form a third opening exposing a second portion of the pad having a second associated area, the second associated area being larger than the first associated area; and etching the mold structure to form a fourth opening having a width larger than a width of the third opening.

Abstract: A method of fabricating a nonvolatile memory device with a three-dimensional structure includes alternately stacking first and second material layers in two or more layers on a semiconductor substrate, forming trenches penetrating the stacked first and second material layers by performing a first etching process, and removing the second material layers exposed in the trenches by performing a second etching process. The first and second material layers are formed of materials that have the same main component but have different impurity contents, respectively.

Abstract: A method of manufacturing a nonvolatile memory device having a three-dimensional memory device includes alternately stacking a plurality of first and second material layers having a different etching selectivity on a semiconductor substrate; forming an opening penetrating the plurality of first and second material layers; removing the first material layers exposed by the opening to form extended portions extending in a direction perpendicular to the semiconductor substrate from the opening; conformally forming a charge storage layer along a surface of the opening and the extended portions; and removing the charge storage layer formed on sidewalls of the second material layers to locally form the charge storage layer patterns in the extended portions.

Abstract: A method of manufacturing a nonvolatile memory device having a three-dimensional memory device includes alternately stacking a plurality of first and second material layers having a different etching selectivity on a semiconductor substrate; forming an opening penetrating the plurality of first and second material layers; removing the first material layers exposed by the opening to form extended portions extending in a direction perpendicular to the semiconductor substrate from the opening; conformally forming a charge storage layer along a surface of the opening and the extended portions; and removing the charge storage layer formed on sidewalls of the second material layers to locally form the charge storage layer patterns in the extended portions.

Abstract: In a method of forming a capacitor, a first mold layer pattern including a first insulating material may be formed on a substrate. The first mold layer pattern may have a trench. A supporting layer including a second insulating material may be formed in the trench. The second insulating material may have an etching selectivity with respect to the first insulating material. A second mold layer may be formed on the first mold layer pattern and the supporting layer pattern. A lower electrode may be formed through the second mold layer and the first mold layer pattern. The lower electrode may make contact with a sidewall of the supporting layer pattern. The first mold layer pattern and the second mold layer may be removed. A dielectric layer and an upper electrode may be formed on the lower electrode and the supporting layer pattern.

Abstract: In a vertical-type non-volatile memory device, an insulation layer pattern is provided on a substrate, the insulation layer pattern having a linear shape. Single-crystalline semiconductor patterns are provided on the substrate to make contact with both sidewalls of the insulation layer pattern, the single-crystalline semiconductor patterns having a pillar shape that extends in a vertical direction relative to the substrate. A tunnel oxide layer is provided on the single-crystalline semiconductor pattern. A lower electrode layer pattern is provided on the tunnel oxide layer and on the substrate. A plurality of insulation interlayer patterns is provided on the lower electrode layer pattern, the insulation interlayer patterns being spaced apart from one another by a predetermined distance along the single-crystalline semiconductor pattern. A charge-trapping layer and a blocking dielectric layer are sequentially formed on the tunnel oxide layer between the insulation interlayer patterns.