Whenever substrates are rotationally and continuously conveyed in a vacuum recipient around a common axis and past a magnetron sputter source, sputtering of the target, rotating around a central target axis, by the stationary magnetron plasma is adapted to the azimuthal extents radially differently spaced areas of the substrates become exposed to the target thereby improving homogeneity of deposited layer thickness on the substrates and ensuring that the complete sputter surface of the target is net-sputtered.

Gas boxes for providing semiconductor processing gases are provided that incorporate a cross-flow ventilation system that may effectively remove potentially leaking gases from within the gas box at significantly lower volumetric flow rates than are possible with conventional gas box ventilation systems.

A method for processing a workpiece, a plasma processing apparatus and a semiconductor device are provided. The method includes placing a workpiece including a spacer layer on a workpiece support in a chamber; selecting a composition modulation gas to modulate a volume ratio of carbon and fluorine to process the workpiece, the composition modulation gas includes one or more molecules, the volume ratio of carbon and fluorine is indicative of a distribution of carbon-based polymer deposited on the spacer layer; generating one or more species using one or more plasmas from a process gas to create a mixture, the process gas includes an etching gas and the composition modulation gas; and exposing the workpiece to the mixture to form a polymer layer on at least a portion of the spacer layer and to etch at least a portion of the spacer layer.

A system and a method for preventing oil splash in a rotary-type plasma head is provided, including a nozzle unit through which plasma is discharged, a rotating body unit, in which the nozzle unit is attached to and detached from one side of the rotating body unit, the other side of the rotating body unit is connected to a housing unit, and the rotating body unit is configured to drive the nozzle unit to rotate, and an oil cover unit connected to one side of the nozzle unit and configured to surround the rotating body unit from outside, to prevent oil vapor or oil micro-droplets discharged through joints of components of the rotating body unit from leaking outside.

Processing chambers and methods to disrupt the boundary layer are described. The processing chamber includes a showerhead and a substrate support therein. The showerhead and the substrate support are spaced to have a process gap between them. In use, a boundary layer is formed adjacent to the substrate support or wafer surface. As the reaction occurs at the wafer surface, reaction products and byproduct are produced, resulting in reduced chemical utilization rate. The processing chamber and methods described disrupt the boundary layer by changing one or more process parameters (e.g., pressure, flow rate, time, process gap or temperature of fluid passing through the showerhead).

An ion implantation system includes an ion implanter containing an ion source unit and a dopant source gas supply system. The system includes a dopant source gas storage tank inside a gas box container located remotely to the ion implanter and a dopant source gas supply pipe configured to supply a dopant source gas from the dopant source gas storage tank to the ion source unit. The dopant source gas supply pipe includes an inner pipe, an outer pipe enclosing the inner pipe, a first pipe adaptor coupled to first end of respective inner and outer pipes, and a second pipe adaptor coupled to seconds end of respective inner and outer pipes opposite the first end. The first pipe adaptor connects the inner pipe to the dopant source gas storage tank and the second pipe adaptor connects the inner pipe to the ion source unit.

An etching method includes: (a) providing, on a support, a substrate having the first region covering the second region and the second region defining a recess receiving the first region, (b) etching the first region until or immediately before the second region is exposed, (c) exposing the substrate to plasma generated from a first process gas containing C and F atoms using a first RF signal and forming a deposit on the substrate, (d) exposing the deposit to plasma generated from a second process gas containing an inert gas using a first RF signal and selectively etching the first region to the second region, and (e) repeating (c) and (d). (c) includes using the RF signal with a frequency of 60 to 300 MHz and/or setting the support to 100 to 200° C. to control a ratio of C to F atoms in the deposit to greater than 1.

A member for semiconductor manufacturing apparatus has a ceramic plate, a porous plug, an insulating lid, and pores. The ceramic plate has a wafer placement surface as an upper surface. The porous plug is disposed in a plug insertion hole penetrating the ceramic plate in an up-down direction, and allows a gas to flow. The insulating lid is provided in contact with an upper surface of the porous plug, and exposed to the wafer placement surface. A plurality of pores are provided in the insulating lid, and penetrate the insulating lid in an up-down direction.

A semiconductor device manufacturing method comprising loading a substrate into a substrate treatment apparatus, performing a deposition process on the substrate, and cleaning the substrate treatment apparatus. The substrate treatment apparatus includes a housing defining a treatment area in which the deposition process is performed, a gas supply supplying a first process gas at a flow rate of 1000 sccm to 15000 sccm and supplying a second process gas, a remote plasma supply connected to the gas supply, generating a first process plasma and a second process plasma by applying RF power to plasma-process the first process gas and the second process gas, and a shower head installed in the housing to supply the first process plasma and the second process plasma to the treatment area. The second process plasma cleans a membrane material deposited on an inner wall of the housing.

A housing in an active gas generator according to the present disclosure includes a peripheral stepped region formed along an outer periphery of a central bottom region, the peripheral stepped region being higher in formed height than the central bottom region. A high-voltage-electrode dielectric film on the peripheral stepped region forms a gas separation structure for separating a gas stream into a feeding space and an active gas generating space including a discharge space. A vacuum pump disposed outside the housing sets the feeding space under vacuum.