Plasma applications are disclosed that operate with argon and other molecular gases at atmospheric pressure, and at low temperatures, and with high concentrations of reactive species. The plasma apparatus and the enclosure that contains the plasma apparatus and the substrate are substantially free of particles, so that the substrate does not become contaminated with particles during processing. The plasma is developed through capacitive discharge without streamers or micro-arcs. The techniques can be employed to remove organic materials from a substrate, thereby cleaning the substrate; to activate the surfaces of materials, thereby enhancing bonding between the material and a second material; to etch thin films of materials from a substrate; and to deposit thin films and coatings onto a substrate; all of which processes are carried out without contaminating the surface of the substrate with substantial numbers of particles.

Manufacturing equipment with which steps from processing to sealing of an organic compound film can be continuously performed is provided. The manufacturing equipment enables continuous processing of a patterning step of a light-emitting device and a light-receiving device and a step of sealing top and side surfaces of organic layers to prevent the top and side surfaces from being exposed to the air, which allows formation of the light-emitting device and the light-receiving device each of which has a minute structure, high luminous, and high reliability. This manufacturing equipment can be built in an in-line manufacturing system where apparatuses are arranged according to the order of process steps for the light-emitting device and the light-receiving device, resulting in high throughput manufacturing.

Embodiments disclosed herein include a method for determining a temperature error of a pyrometer. In an embodiment, the method comprises measuring a first signal with a first sensor of the pyrometer and measuring a second signal with a second sensor of the pyrometer. In an embodiment, the method further comprises determining a reflectivity of a reflector plate from the first signal and the second signal, and determining the temperature error using the reflectivity.

A method of operating an apparatus for laser annealing, includes reducing temporal or spatial coherency of a plurality of laser beams by beam superimposing; and reducing an electric field inner product magnitude of beams having the reduced temporal or spatial coherency by a fly eye lens array to reduce coherency, and/or by modifying a polarization state between the beams by beam superimposing.

An etching method is provided. In the etching method, a protective film-forming gas including an amine gas is supplied to a substrate having a surface on which a first film and a second film are formed, the first film and the second film having respective properties of being etched by an etching gas, and a protective film is formed to cover the first film such that the first film is selectively protected between the first film and the second film when the etching gas is supplied. Further, the second film is selectively etched by supplying the etching gas to the substrate after the protective film is formed.

There is provided a technique that includes: etching a portion of a first film formed on a surface of a substrate by performing a cycle a predetermined number of times, the cycle including: supplying an etching gas into a process chamber while raising an internal pressure of the process chamber in a state in which the substrate having the first film formed on the surface of the substrate is accommodated in the process chamber; and lowering the internal pressure of the process chamber by exhausting an interior of the process chamber in a state in which supply of the etching gas into the process chamber is stopped.

A mounting table is provided. The mounting table includes an electrostatic chuck configured to mount thereon a target object and attract and hold the target object using an electrostatic force, and a gas supply line configured to supply a gas to a gap between the target object mounted on the electrostatic chuck and the electrostatic chuck via the electrostatic chuck. The mounting table further includes at least one irradiation unit configured to irradiate light having a predetermined wavelength to the gas flowing through the gas supply line or to the gas supplied to the gap between the target object and the electrostatic chuck to ionize the gas.

A plasma processing apparatus includes: a first electrode on which a substrate is placed; a plasma generation source that generates plasma; a bias power supply that supplies bias power to the first electrode; a source power supply that supplies source power to the plasma generation source; and a controller. The controller performs a control such that a first state and a second state of the source power are alternately applied in synchronization with a high frequency cycle of the bias power, or a phase within one cycle of a reference electrical state indicating any one of a voltage, a current and an electromagnetic field measured in a power feed system of the bias power, and performs a control to turn OFF the source power at least at a negative side peak of the phase within one cycle of the reference electrical state.

A heater controller controls power supplied to a heater capable of adjusting the temperature of a placement surface such that the heater reaches a set temperature. A temperature monitor measures the power supplied in the non-ignited state where the plasma is not ignited and in the transient state where the power supplied to the heater decreases after the plasma is ignited, while the power is controlled such that the temperature of the heater becomes constant. A parameter calculator calculates a heat input amount and the thermal resistance by using the power supplied in the non-ignited state and in the transient state to perform a fitting on a calculation model for calculating the power supplied in the transient state. A set temperature calculator calculates the set temperature of the heater at which the wafer reaches the target temperature, using the heat input amount and thermal resistance.

Systems and methods may be used to produce coated components. Exemplary semiconductor chamber components may include an aluminum alloy comprising nickel and may be characterized by a surface. The surface may include a corrosion resistant coating. The corrosion resistant coating may include a conformal layer and a non-metal layer. The conformal layer may extend about the semiconductor chamber component. The non-metal oxide layer may extend over a surface of the conformal layer. The non-metal oxide layer may be characterized by an amorphous microstructure having a hardness of from about 300 HV to about 10,000 HV. The non-metal oxide layer may also be characterized by an sp.sup.2 to sp.sup.3 hybridization ratio of from about 0.01 to about 0.5 and a hydrogen content of from about 1 wt. % to about 35 wt. %.