摘要:
A method is provided for reducing the metal content and controlling the metal depth profile of a gate dielectric layer in a gate stack. The method includes providing a substrate in a process chamber, depositing a gate dielectric layer on the substrate, where the gate dielectric layer includes a metal element. The metal element is selectively etched from at least a portion of the gate dielectric layer to form an etched gate dielectric layer with reduced metal content, and a gate electrode layer is formed on the etched gate dielectric layer.
摘要:
A semiconductor memory device with a floating gate that includes a plurality of nanoclusters (21) and techniques useful in the manufacturing of such a device are presented. The device is formed by first providing a semiconductor substrate (12) upon which a tunnel dielectric layer (14) is formed. A plurality of nanoclusters (19) is then grown on the tunnel dielectric layer (14). The growth of the nanoclusters (19) may be accomplished using low pressure chemical vapor deposition (LPCVD) or ultra high vacuum chemical vapor deposition (UHCVD) processes. Such growth may be facilitated by formation of a nitrogen-containing layer (502) overlying the tunnel dielectric layer (14). After growth of the nanoclusters (21), a control dielectric layer (20) is formed over the nanoclusters (21). In order to prevent oxidation of the formed nanoclusters (21), the nanoclusters (21) may be encapsulated using various techniques prior to formation of the control dielectric layer (20). A gate electrode (24) is then formed over the control dielectric (20), and portions of the control dielectric, the plurality of nanoclusters, and the gate dielectric that do not underlie the gate electrode are selectively removed. After formation of spacers (35), source and drain regions (32, 34) are then formed by implantation in the semiconductor layer (12) such that a channel region is formed between the source and drain regions (32, 34) underlying the gate electrode (24).
摘要:
A semiconducting device with a multilayer sidewall spacer and method of forming are described. In one embodiment, the method includes providing a substrate containing a patterned structure on a surface of the substrate and depositing a first spacer layer over the patterned structure at a first substrate temperature, where the first spacer layer contains a first material. The method further includes depositing a second spacer layer over the patterned substrate at a second substrate temperature that is different from the first substrate temperature, where the first and second materials contain the same chemical elements, and the depositing steps are performed in any order. The first and second spacer layers are then etched to form the multilayer sidewall spacer on the patterned structure.
摘要:
The present invention generally provides a method for preparing an oxynitride film on a substrate. A surface of the substrate is exposed to oxygen radicals formed by ultraviolet (UV) radiation induced dissociation of a first process gas comprising at least one molecular composition comprising oxygen to form an oxide film on the surface. The oxide film is exposed to nitrogen radicals formed by plasma induced dissociation of a second process gas comprising at least one molecular composition comprising nitrogen using plasma based on microwave irradiation via a plane antenna member having a plurality of slits to nitridate the oxide film and form the oxynitride film.
摘要:
A semiconductor memory device with a floating gate that includes a plurality of nanoclusters (21) and techniques useful in the manufacturing of such a device are presented. The device is formed by first providing a semiconductor substrate (12) upon which a tunnel dielectric layer (14) is formed. A plurality of nanoclusters (19) is then grown on the tunnel dielectric layer (14). After growth of the nanoclusters (21), a control dielectric layer (20) is formed over the nanoclusters (21). In order to prevent oxidation of the formed nanoclusters (21), the nanoclusters (21) may be encapsulated using various techniques prior to formation of the control dielectric layer (20). A gate electrode (24) is then formed over the control dielectric (20), and portions of the control dielectric, the plurality of nanoclusters, and the gate dielectric that do not underlie the gate electrode are selectively removed. After formation of spacers (35), source and drain regions (32, 34) are then formed by implantation in the semiconductor layer (12) such that a channel region is formed between the source and drain regions (32, 34) underlying the gate electrode (24).
摘要:
A method of patterning a substrate. A sacrificial film is formed over a substrate and a pattern created therein. A first spacer layer is conformally deposited over the patterned sacrificial film and at least one horizontal portion of the first spacer layer is removed while vertical portions of the first spacer layer remain. A second spacer layer is conformally deposited over the patterned sacrificial film and the remaining portions of the first spacer layer. At least one horizontal portion of the second spacer layer is removed while vertical portions of the second spacer layer remain. Conformal deposition of the first and second spacer layers is optionally repeated one or more times. Conformal deposition of the first layer is optionally repeated. Then, one of the first or second spacer layers is removed while substantially leaving the vertical portions of the remaining one of the first or second spacer layers.
摘要:
A method and system are provided for monitoring status of a system component in a process chamber of a batch type processing system. The method includes exposing a system component to light from a light source and monitoring interaction of the light with the system component to determine status of the system component. The method can detect light transmission and/or light reflection from a system component during a process that can include a chamber cleaning process, a chamber conditioning process, a substrate etching process, and a substrate film formation process. The system component can be a consumable system part such as a process tube, a shield, a ring, a baffle, and a liner, and can further contain a protective coating.
摘要:
A semiconducting device with a dual sidewall spacer and method of forming are provided. The method includes: depositing a first spacer layer over a patterned structure, the first spacer layer having a seam propagating through a thickness of the first spacer layer near an interface region of a surface of the substrate and a sidewall of the patterned structure, etching the first spacer layer to form a residual spacer at the interface region, where the residual spacer coats less than the entirety of the sidewall of the patterned structure, depositing a second spacer layer on the residual spacer and on the sidewall of the patterned structure not coated by the residual spacer, the second spacer layer being seam-free on the seam of the residual spacer, and etching the second spacer layer to form a second spacer coating the residual spacer and coating the sidewall of the patterned structure not coated by the residual spacer.
摘要:
A method and control system for treating a hafnium-based dielectric processing system in which a system component of the processing system is exposed to a chlorine-containing gas. A residual hafnium by-product remaining in the processing system after a hafnium removal process is reacted with a chlorine-containing etchant derived from the chlorine-containing gas. A chlorinated hafnium product is volatilized for exhaustion from the processing system. The control system can utilize a computer readable medium to introduce a chlorine-containing gas to the processing system, to adjust at least one of a temperature and a pressure in the processing system to produce from the chlorine-containing gas a chlorine-containing etchant for dissolution of a residual hafnium by-product remaining in the processing system after a hafnium silicate, hafnium oxide, or hafnium oxynitride removal process, and to exhaust a chlorinated hafnium product from the processing system.
摘要:
Ultra-thin oxynitride layers are formed utilizing low-pressure processing to achieve self-limiting oxidation of substrates and provide ultra-thin oxynitride. The substrates to be processed can contain an initial dielectric layer such as an oxide layer, an oxynitride layer, or a nitride layer, or alternatively can lack an initial dielectric layer. The processing can be carried out using a batch type process chamber or a single-wafer process chamber.