摘要:
A semiconductor device includes a first metal interconnection layer on a semiconductor substrate, an intermetal dielectric layer on the first metal interconnection layer and a second metal interconnection layer formed on the intermetal dielectric layer. A contact stud electrically connects the first and second metal interconnection layers through the intermetal dielectric layer, and includes a titanium/aluminum (TiAlx) core extending from the first metal interconnection layer toward the second metal interconnection layer. In method embodiments, a portion of an insulating layer of a semiconductor substrate is removed to form a hole that exposes an underlying conductive layer. A glue layer, e.g., a titanium (Ti) layer, is formed on bottom and sidewalls of the hole. A Ti seed layer is formed on the glue layer in the hole. An aluminum-containing layer is formed on the Ti seed layer. The substrate is thermally treated to form a contact stud including a TiAlx core.
摘要:
Methods of forming an integrated circuit device can include forming an interlevel dielectric film on an integrated circuit substrate including a conductive portion thereof. The interlevel dielectric film includes a contact hole therein exposing a portion of the conductive portion of the integrated circuit substrate, and the dielectric film includes a trench therein communicating with the contact hole wherein the trench is in a surface of the interlevel dielectric film opposite the integrated circuit substrate. A first metal layer is formed in the contact hole preferentially with respect to formation of the first metal layer on a surface of the interlevel dielectric film opposite the integrated circuit substrate. After preferentially forming the first metal layer in the contact hole, a second metal layer is formed on the surface of the interlevel dielectric film opposite the integrated circuit substrate.
摘要:
A copper-plating electrolyte includes an aqueous copper salt solution, a water-soluble &bgr;-naphtholethoxylate compound having the formula wherein n is an integer from 10 to 24, one selected from the group consisting of a disulfide having the formula XO3S(CH2)3SS(CH2)3SOX3 and a water-soluble mercaptopropanesulfonic acid or salt thereof having the formula HS(CH2)3SO3X, where X is sodium, potassium, or hydrogen, a water-soluble polyethylene glycol having a molecular weight ranging from about 4,600 to about 10,000, and a water-soluble polyvinylpyrrolidone having a molecular weight ranging from about 10,000 to about 1,300,000.
摘要:
A semiconductor device having a capacitor. The capacitor includes a first electrode, a dielectric layer formed of a metal oxide layer including a Ta2O5 layer, and a second electrode composed of first and second metal nitride layers sequentially stacked. Each of the first and second metal nitride layers has a TiN layer and a WN layer. The second electrode of the capacitor is a double-layered structure having the first and second metal nitride layers, and thus annealing after forming the second electrode is performed at 750° C. or less, to thereby reduce an equivalent oxide thickness of the dielectric layer.
摘要翻译:一种具有电容器的半导体器件。 电容器包括第一电极,由包括Ta 2 O 5层的金属氧化物层形成的电介质层和由顺序堆叠的第一和第二金属氮化物层构成的第二电极。 第一和第二金属氮化物层中的每一个具有TiN层和WN层。 电容器的第二电极是具有第一和第二金属氮化物层的双层结构,因此在750℃或更低的温度下进行形成第二电极之后的退火,从而降低电介质层的等效氧化物厚度 。
摘要:
The capacitor of semiconductor devices includes a first electrode, a dielectric layer formed of a metal oxide layer including a Ta2O5 layer, and a second electrode composed of first and second metal nitride layers sequentially stacked. First and second metal nitride layers are a TiN layer and a WN layer. The second electrode of the capacitor is a double-layered structure having the first and second metal nitride layers, and thus annealing after forming the second electrode is performed at 750° C. or less to avoid increasing an equivalent oxide thickness of the dielectric layer.
摘要翻译:半导体器件的电容器包括第一电极,由包括Ta 2 O 5层的金属氧化物层形成的电介质层和由顺序层叠的第一和第二金属氮化物层构成的第二电极。 第一和第二金属氮化物层是TiN层和WN层。 电容器的第二电极是具有第一和第二金属氮化物层的双层结构,因此在形成第二电极之后的退火在750℃以下进行,以避免增加电介质层的等效氧化物厚度。
摘要:
A method of manufacturing an electrical interconnection of a semiconductor device produces an erosion protecting plug in a contact hole to protect a selected portion of an interlayer dielectric layer when the interlayer dielectric layer is being etched to form a recess for a conductive line. The contact hole is formed in the interlayer dielectric layer. The contact hole is filled with an organic material to form the erosion protecting plug. The organic material is a photoresist material or an organic polymer. A photoresist pattern is formed for exposing the erosion protecting plug and a portion of the interlayer dielectric layer adjacent to the erosion protecting plug. A recess which extends down to the contact hole is formed by etching the portion of the interlayer dielectric layer which is exposed by the photoresist pattern. The erosion protecting plug and the photoresist pattern are then removed. A conductive line filling the recess and a contact filling the contact hole are then formed.
摘要:
A method for fabricating a capacitor on a substrate includes the steps of forming an insulating layer on the substrate, and forming the first plate electrode on the insulating layer. A first dielectric layer is then formed on the plate electrode, and a first common storage electrode is formed on the first dielectric layer. A contact hole is then formed through the insulating layer, the first plate electrode, the first dielectric layer, and the first common storage electrode, thereby exposing a predetermined portion of the substrate. A first spacer is formed on a sidewall of the contact hole, and a conductive plug is formed in the contact hole extending from the substrate to the first common storage electrode.
摘要:
A method of fabricating a capacitor for a integrated circuit device includes the steps of forming a lower capacitor electrode on an integrated circuit substrate, and forming a dielectric layer on the lower capacitor electrode opposite the integrated circuit substrate. A titanium nitride barrier layer is deposited by chemical vapor deposition on the dielectric layer opposite the integrated circuit substrate to a thickness in the range of 50 .ANG. to 500 .ANG. using TiCl.sub.4 as a source gas. The titanium nitride barrier layer is annealed, and an upper electrode is formed on the titanium nitride barrier layer opposite the integrated circuit substrate.