A method for fabricating a capacitor structure is described. The method for metal insulator metal capacitor in an integrated circuit device includes forming a first dielectric layer on a substrate. The first dielectric layer has a linear trench feature in which the capacitor is disposed. A bottom capacitor plate is formed in a lower portion of the trench. The bottom capacitor plate has an extended top face so that the extended top face extends upwards in a central region of the bottom capacitor plate metal relative to side regions. A high-k dielectric layer is formed over the extended top face of the bottom capacitor plate. A top capacitor plate is formed in a top, remainder portion of the trench on top of the high-k dielectric layer.

Described herein is a technique capable of improving a quality of a substrate processing. According to one aspect of the technique described herein, there is provided a method of manufacturing a semiconductor device including: (a) receiving substrate data including at least one of a stacked number of layers of a device formed on a substrate and a structure of the device; (b) setting an apparatus parameter corresponding to the substrate data; (c) supporting the substrate corresponding to the substrate data above a substrate support; (d) elevating a temperature of the substrate based on the apparatus parameter while the substrate is separated from a surface of the substrate support; (e) placing the substrate on the substrate support after (d); and (f) processing the substrate in a process chamber.

A semiconductor device with favorable electrical characteristics is provided. A source electrode and a drain electrode of a channel-etched transistor are each made to have a stacked-layer structure including a first conductive layer and a second conductive layer. A silicide that contains a metal element contained in the second conductive layer and nitrogen is formed to be in contact with a top surface and a side surface of the second conductive layer. Before etching of the first conductive layer, the silicide is formed by exposing the second conductive layer to an atmosphere containing silane, and plasma treatment is performed in a nitrogen atmosphere without exposure to the air.

Disclosed are an array substrate of a thin-film transistor liquid crystal display device and a method for manufacturing the same. The array substrate includes a plurality of data lines, a plurality of dummy data lines, a plurality of first gate lines, a plurality of second gate lines, and a plurality of groups of pixel units. Each group of pixel units includes an odd-numbered column of first thin film transistors and an even-numbered column of second thin film transistors. First ends and second ends of the dummy data lines are connected respectively to two common voltage electrode lines, which are arranged on the substrate in a transverse direction. The method includes steps of: forming a plurality of gate lines and two common voltage electrode lines; forming a source, a drain, and a plurality of data lines; and forming a plurality of pixel electrodes and a plurality of dummy data lines. A light shielding electrode line provided has good voltage driving uniformity.

A semiconductor device includes a substrate, semiconductor 2-D material layer, a conductive 2-D material layer, a gate dielectric layer, and a gate electrode. The semiconductor 2-D material layer is over the substrate. The conductive 2-D material layer extends along a source/drain region of the semiconductor 2-D material layer, in which the conductive 2-D material layer comprises a group-IV element. The gate dielectric layer extends along a channel region of the semiconductor 2-D material layer. The gate electrode is over the gate dielectric layer.

One or more embodiments described herein generally relate to selective deposition of substrates in semiconductor processes. In these embodiments, a precursor is delivered to a process region of a process chamber. A plasma is generated by delivering RF power to an electrode within a substrate support surface of a substrate support disposed in the process region of the process chamber. In embodiments described herein, delivering the RF power at a high power range, such as greater than 4.5 kW, advantageously leads to greater plasma coupling to the electrode, resulting in selective deposition to the substrate, eliminating deposition on other process chamber areas such as the process chamber side walls. As such, less process chamber cleans are necessary, leading to less time between depositions, increasing throughput and making the process more cost-effective.

Provided is a process for the vapor deposition of molybdenum or tungsten, and the use of molybdenum hexacarbonyl (Mo(CO).sub.6) or tungsten hexacarbonyl (W(CO).sub.6) for such deposition, e.g., in the manufacture of semiconductor devices in which molybdenum-containing or tungsten-containing films are desired. In accordance with one aspect of the invention, molybdenum hexacarbonyl (Mo(CO).sub.6) has been found in vapor deposition processes such as chemical vapor deposition (CVD) to provide low resistivity, high deposition rate films in conjunction with a pulsed deposition process in which a step involving a brief pulse of H.sub.2O is utilized. This pulsing with H.sub.2O vapor was found to be effective in reducing the carbon content of films produced from Mo(CO).sub.6-based CVD processes.

A method of depositing an atomic layer of a metal-containing film including a plurality of deposition cycles is provided. Each of the plurality of deposition cycles may include adsorbing a hydrogen (H)-containing compound on a wafer surface in a chamber, treating a wafer on which the H-containing compound is adsorbed with hydrogen (H.sub.2) gas, and providing a metal precursor to the wafer to react with the H-containing compound to form the metal-containing film.

This application relates to a memory device and a method for manufacturing the same, including: a substrate on which an insulation structure and a plurality of first active structures are formed is provided. The plurality of first active structures are arranged at intervals in the insulation structure. A word line conductive layer is formed on the substrate by a physical vapor deposition process. The word line conductive layer is patterned and etched to obtain a plurality of word line structures arranged in parallel and at intervals and filling slots located between adjacent word line structures. The filling slots comprise first filling slots that expose both parts of top surfaces of the first active structures and parts of the top surface of the insulation structure. Second active structures are formed in the first filling slots, and isolation structures are formed in the first filling slots.

A method for depositing a metal layer on a wafer is disclosed. A PVD chamber is provide having therein a wafer chuck for holding a wafer to be processed, a target situated above the wafer chuck, a magnet positioned on a backside of the target, and a DC power supply for supplying a DC voltage to the target. The target is a metal or a metal alloy having ferromagnetism property. A paste process is performed to the PVD chamber. The paste process includes sequential steps of: admitting a working gas into the PVD chamber; and igniting the working gas in cascade stages. The wafer is then loaded into the PVD chamber and positioned onto the wafer chuck. A deposition process is then performed to deposit a metal layer sputtered from the target onto the wafer.