Abstract: A semiconductor device includes a gate trench across an active region of a semiconductor substrate, a gate structure filling the gate trench, and source/drain regions formed in the active region at respective sides of the gate structure. The gate structure includes a sequentially stacked gate electrode and insulating capping pattern, and a gate dielectric layer between the gate electrode and the active region. The gate electrode is located at a lower level than an upper surface of the active region and includes a barrier conductive pattern and a gate conductive pattern. The gate conductive pattern includes a first part having a first width and a second part having a second width greater than the first width. The barrier conductive pattern is interposed between the first part of the gate conductive pattern and the gate dielectric layer.

Abstract: A semiconductor device includes: a semiconductor substrate having a trench therein, a metal-containing barrier layer extending along an inner wall of the trench and defining a wiring space in the trench, the wiring space having a first width along a first direction, and a metal-containing conductive line on the metal-containing barrier layer in the wiring space, and including at least one metal grain having a particle diameter of about the first width along the first direction.

Abstract: Methods of manufacturing non-volatile memory devices may include separating first phase-change material groups and second phase-change material groups, which have different sizes, from a target including phase-change materials and faulting a phase-change material layer on an object by using the first phase-change material groups and the second phase-change material groups.

Abstract: A semiconductor device includes a gate trench across an active region of a semiconductor substrate, a gate structure filling the gate trench, and source/drain regions formed in the active region at respective sides of the gate structure. The gate structure includes a sequentially stacked gate electrode and insulating capping pattern, and a gate dielectric layer between the gate electrode and the active region. The gate electrode is located at a lower level than an upper surface of the active region and includes a barrier conductive pattern and a gate conductive pattern. The gate conductive pattern includes a first part having a first width and a second part having a second width greater than the first width. The barrier conductive pattern is interposed between the first part of the gate conductive pattern and the gate dielectric layer.

Abstract: An example embodiment relates to a method including forming a bottom electrode and an insulating layer on a substrate, the insulating layer defining a first opening that exposes a portion of the bottom electrode. The method includes forming a variable resistance material pattern, including a plurality of elements, to fill the first opening. The variable resistance material pattern may be doped with a dopant that includes at least one of the plurality of elements in the variable resistance material pattern. The method includes forming a top electrode on the variable resistance material pattern.

Abstract: A phase change structure includes a first phase change material layer pattern and a second phase change material layer pattern. The first phase change material layer pattern may partially fill a minute structure, and the second phase change material layer pattern may fully fill the minute structure. The first phase change material layer pattern may include a first phase change material, and the second phase change material layer pattern may include a second phase change material having a composition substantially different from a composition of the first phase change material.

Abstract: A phase change structure includes a first phase change material layer pattern and a second phase change material layer pattern. The first phase change material layer pattern may partially fill a minute structure, and the second phase change material layer pattern may fully fill the minute structure. The first phase change material layer pattern may include a first phase change material, and the second phase change material layer pattern may include a second phase change material having a composition substantially different from a composition of the first phase change material.

Abstract: A semiconductor device includes: a semiconductor substrate having a trench therein, a metal-containing barrier layer extending along an inner wall of the trench and defining a wiring space in the trench, the wiring space having a first width along a first direction, and a metal-containing conductive line on the metal-containing barrier layer in the wiring space, and including at least one metal grain having a particle diameter of about the first width along the first direction.

Abstract: An example embodiment relates to a method including forming a bottom electrode and an insulating layer on a substrate, the insulating layer defining a first opening that exposes a portion of the bottom electrode. The method includes forming a variable resistance material pattern, including a plurality of elements, to fill the first opening. The variable resistance material pattern may be doped with a dopant that includes at least one of the plurality of elements in the variable resistance material pattern. The method includes forming a top electrode on the variable resistance material pattern.

Abstract: Methods of manufacturing non-volatile memory devices may include separating first phase-change material groups and second phase-change material groups, which have different sizes, from a target including phase-change materials and faulting a phase-change material layer on an object by using the first phase-change material groups and the second phase-change material groups.

Abstract: A phase change structure includes a first phase change material layer pattern and a second phase change material layer pattern. The first phase change material layer pattern may partially fill a high aspect ratio structure, and the second phase change material layer pattern may fully fill the high aspect ratio structure. The first phase change material layer pattern may include a first phase change material, and the second phase change material layer pattern may include a second phase change material having a composition substantially different from a composition of the first phase change material.

Abstract: Example embodiments relate to a method of manufacturing a capacitor and a method of manufacturing a semiconductor device using the same. Other example embodiments relate to a method of manufacturing a capacitor having improved characteristics and a method of manufacturing a semiconductor device using the same. In a method of manufacturing a capacitor having improved characteristics, an insulation layer, including a pad therein, may be formed on a substrate. An etch stop layer may be formed on the insulation layer. A mold layer may be formed on the etch stop layer. The mold layer may be partially etched by a first etching process to form a first contact hole exposing the etch stop layer. The mold layer may be partially etched by a second etching process to form a second contact hole. The exposed etch stop layer may be etched by a third etching process to form a third contact hole exposing the pad.

Abstract: Example embodiments of the present invention relate to methods of manufacturing a semiconductor device. Other example embodiments of the present invention relate to methods of manufacturing a semiconductor device having a gate electrode. In the method of manufacturing the semiconductor device, a gate electrode may be formed on a semiconductor substrate. Damage in the semiconductor substrate and a sidewall of the gate electrode may be cured, or repaired, by a radical re-oxidation process to form an oxide layer on the semiconductor substrate and the gate electrode.

Abstract: A semiconductor device having reduced pitting may be formed from isolation layer patterns on a semiconductor substrate defining an active region, a tunnel oxide layer on the active region, the tunnel oxide layer having a nitrified surface, a floating gate on the tunnel oxide layer, a dielectric layer on the floating gate, and a control gate on the dielectric layer.

Abstract: Example embodiments relate to a method of manufacturing a capacitor and a method of manufacturing a semiconductor device using the same. Other example embodiments relate to a method of manufacturing a capacitor having improved characteristics and a method of manufacturing a semiconductor device using the same. In a method of manufacturing a capacitor having improved characteristics, an insulation layer, including a pad therein, may be formed on a substrate. An etch stop layer may be formed on the insulation layer. A mold layer may be formed on the etch stop layer. The mold layer may be partially etched by a first etching process to form a first contact hole exposing the etch stop layer. The mold layer may be partially etched by a second etching process to form a second contact hole. The exposed etch stop layer may be etched by a third etching process to form a third contact hole exposing the pad.

Abstract: A pad structure, a method of forming a pad structure, a semiconductor device having a pad structure and a method of manufacturing a semiconductor device are disclosed. The pad structure may include a first pad, a second pad, a third pad and/or a spacer. The first pad may contact a contact region on a substrate. The first pad may include doped polysilicon. The second pad may contact the first pad. The second pad may include a metal silicide or a metal silicongermanium. The third pad may contact the second pad. The third pad may include a conductive material (e.g., doped polysilicon, a metal or a metal nitride). The spacer may be formed on sidewalls of the second and the third pads.

Abstract: Example embodiments of the present invention relate to methods of manufacturing a semiconductor device. Other example embodiments of the present invention relate to methods of manufacturing a semiconductor device having a gate electrode. In the method of manufacturing the semiconductor device, a gate electrode may be formed on a semiconductor substrate. Damage in the semiconductor substrate and a sidewall of the gate electrode may be cured, or repaired, by a radical re-oxidation process to form an oxide layer on the semiconductor substrate and the gate electrode.

Abstract: A method for forming a low-k dielectric layer for a semiconductor device using an ALD process including (a) forming predetermined interconnection patterns on a semiconductor substrate, (b) supplying a first and a second reactive material to a chamber having the substrate therein, thereby adsorbing the first and second reactive materials on a surface of the substrate, (c) supplying a first gas to the chamber to purge the first and second reactive materials that remain unreacted, (d) supplying a third reactive material to the chamber, thereby causing a reaction between the first and second materials and the third reactive material to form a monolayer, (e) supplying a second gas to the chamber to purge the third reactive material that remains unreacted in the chamber and a byproduct; and (f) repeating (b) through (e) a predetermined number of times to form a SiBN ternary layer having a predetermined thickness on the substrate.

Abstract: A method of forming a dielectric layer for a non-volatile memory cell is disclosed. According to the method, a dielectric layer is formed by successively forming a lower oxide layer, a nitride layer and an upper oxide layer on a semiconductor substrate. The lower and upper oxide layers are formed using a radical oxidation process. A method of forming a non-volatile memory cell having the dielectric layer is also disclosed.

Abstract: A method for forming a low-k dielectric layer for a semiconductor device using an ALD process including (a) forming predetermined interconnection patterns on a semiconductor substrate, (b) supplying a first and a second reactive material to a chamber having the substrate therein, thereby adsorbing the first and second reactive materials on a surface of the substrate, (c) supplying a first gas to the chamber to purge the first and second reactive materials that remain unreacted, (d) supplying a third reactive material to the chamber, thereby causing a reaction between the first and second materials and the third reactive material to form a monolayer, (e) supplying a second gas to the chamber to purge the third reactive material that remains unreacted in the chamber and a byproduct; and (f) repeating (b) through (e) a predetermined number of times to form a SiBN ternary layer having a predetermined thickness on the substrate.