Embodiments of the present disclosure generally relate to deposition of high transparency, high-density carbon films for patterning applications. In one embodiment, a method of forming a carbon film on a substrate is provided. The method includes flowing a hydrocarbon-containing gas mixture into a process chamber having a substrate positioned on an electrostatic chuck, wherein the substrate is maintained at a temperature of about 10 C. to about 20 C. and a chamber pressure of about 0.5 mTorr to about 10 Torr, and generating a plasma by applying a first RF bias to the electrostatic chuck to deposit a diamond-like carbon film containing about 60% or greater hybridized sp.sup.3 atoms on the substrate, wherein the first RF bias is provided at a power of about 1800 Watts to about 2200 Watts and at a frequency of about 40 MHz to about 162 MHz.

Systems and methods are provided for evacuating a chamber 101. The evacuation system comprises a cooler 320 coupled with the chamber and a controller 350. The controller is configured to determine whether a property of the cooler or the chamber satisfies one or more conditions. Based on the determination that the property satisfies the one or more conditions, the controller is configured to isolate the cooler from the chamber or control the temperature of the cooler to increase at one or more rates. The controller is further configured to control one or more pumps 330,340 to pump the chamber to a base pressure value.

A processing chamber such as a plasma etch chamber can perform deposition and etch operations, where byproducts of the deposition and etch operations can build up in a vacuum pump system fluidly coupled to the processing chamber. A vacuum pump system may have multiple roughing pumps so that etch gases can be diverted a roughing pump and deposition precursors can be diverted to another roughing pump. A divert line may route unused deposition precursors through a separate roughing pump. Deposition byproducts can be prevented from forming by incorporating one or more gas ejectors or venturi pumps at an outlet of a primary pump in a vacuum pump system. Cleaning operations, such as waferless automated cleaning operations, using certain clean chemistries may remove deposition byproducts before or after etch operations.

According to one embodiment, a plasma processing apparatus includes a chamber, a plasma generator, a gas supplier supplying, a placement part, a depressurization part, and a supporting part. The supporting part includes a mounting part positioned below the placement part and provided with the placement part, and a beam extending from a side surface of the chamber toward a center axis of the chamber. One end of the beam is connected to a side surface of the mounting part. The beam includes a space connected to an outside space of the chamber. A following formula is satisfied, t1>t2, when a thickness of a side portion on the placement part side of side portions of the beam is taken as t1, a thickness of a side portion on an opposite side of the placement part side of the beam is taken as t2.

An object of the invention is to stably supply an electron beam from an electron gun, that is, to prevent variation in intensity of the electron beam. The invention provides a charged particle beam device that includes an electron gun having an electron source, an extraction electrode to which a voltage used for extracting electrons from the electron source is applied, and an acceleration electrode to which a voltage used for accelerating the electrons extracted from the electron source is applied, a first heating unit that heats the extraction electrode, and a second heating unit that heats the acceleration electrode.

The invention relates to charged particle beam generator comprising a charged particle source for generating a charged particle beam, a collimator system comprising a collimator structure with a plurality of collimator electrodes for collimating the charged particle beam, a beam source vacuum chamber comprising the charged particle source, and a generator vacuum chamber comprising the collimator structure and the beam source vacuum chamber within a vacuum, wherein the collimator system is positioned outside the beam source vacuum chamber. Each of the beam source vacuum chamber and the generator vacuum chamber may be provided with a vacuum pump.

An assembly and a method for treating at least one object are disclosed. An ionization chamber/plasma chamber is provided which is connected to a high-voltage source via a high-voltage line. A first valve group has a node and a second valve group has a node, a pump being provided between the first valve group and the second valve group. A treatment chamber is fluidic connectable to the first valve group and the second valve group, and the ionization chamber/plasma chamber is also fluidic connectable to the first valve group and the second valve group.

A nozzle-type electron beam irradiation device includes a vacuum chamber, an electron beam generator disposed in the vacuum chamber, and a vacuum nozzle that is connected to the vacuum chamber so as to guide an electron beam from the electron beam generator and emit the electron beam to the outside. The nozzle-type electron beam irradiation device includes a high-vacuum pump capable of sucking gas from the vicinity of the connecting part of the vacuum nozzle in the vacuum chamber.

Methods for depositing ultrathin films by atomic layer deposition with reduced wafer-to-wafer variation are provided. Methods involve exposing the substrate to soak gases including one or more gases used during a plasma exposure operation of an atomic layer deposition cycle prior to the first atomic layer deposition cycle to heat the substrate to the deposition temperature.

An apparatus provided with a wafer processing chamber that houses a wafer supporting mechanism supporting a wafer and is used to irradiate the wafer supported by the wafer supporting mechanism with an ion beam and a transport mechanism housing chamber that houses a transport mechanism provided underneath the wafer processing chamber and used for moving the wafer supporting mechanism in a substantially horizontal direction, wherein an aperture used for moving the wafer supporting mechanism along with a coupling member coupling the wafer supporting mechanism to the transport mechanism is formed in the direction of movement of the transport mechanism in a partition wall separating the wafer processing chamber from the transport mechanism housing chamber.