Disclosed herein is an apparatus for processing a substrate using an inductively coupled plasma source. An inductively coupled plasma source utilizes a power source, a shield member, and a coil coupled to the power source. In certain embodiments, the coils are arranged with a horizontal spiral grouping and a vertical extending helical grouping. The shield member, according to certain embodiments, utilizes a grounding member to function as a Faraday shield. The embodiments herein reduce parasitic losses and instabilities in the plasma created by the inductively coupled plasma in the substrate processing system.

A method and apparatus for reducing as-deposited and metastable defects relative to amorphous silicon (a-Si) thin films, its alloys and devices fabricated therefrom that include heating an earth shield positioned around a cathode in a parallel plate plasma chemical vapor deposition chamber to control a temperature of a showerhead in the deposition chamber in the range of 350° C. to 600° C. An anode in the deposition chamber is cooled to maintain a temperature in the range of 50° C. to 450° C. at the substrate that is positioned at the anode. In the apparatus, a heater is embedded within the earth shield and a cooling system is embedded within the anode.

A plasma processing apparatus including a plasma processing chamber in which an electrode for placing a substrate to be processed is provided; a power supply; and a control device configured to control the power supply, in which the control device is configured to execute heat-retaining discharge under a first condition in which the substrate is not placed on the electrode inside the plasma processing chamber to generate first plasma to heat an inner wall surface to a first temperature, rapid temperature control discharge under a second condition to generate second plasma inside the plasma processing chamber to heat the inner wall surface to a second temperature higher than the first temperature, and product processing of controlling the power supply under a third condition in a state where the substrate is placed on the electrode to generate third plasma inside the plasma processing chamber to process the substrate.

A substrate processing apparatus, includes a reaction chamber, an outer chamber at least partly surrounding the reaction chamber wherein an intermediate space is formed between the reaction chamber and the outer chamber, at least one heater element, at least one heat distributor in the intermediate space, and at least one heater element feedthrough in the outer chamber allowing at least a part of the at least one heater element to pass through into the intermediate space and to couple with the at least one heat distributor.

In one embodiment, a plasma processing device may include a dielectric window, a vacuum chamber, an energy source, and at least one air amplifier. The dielectric window may include a plasma exposed surface and an air exposed surface. The vacuum chamber and the plasma exposed surface of the dielectric window can cooperate to enclose a plasma processing gas. The energy source can transmit electromagnetic energy through the dielectric window and form an elevated temperature region in the dielectric window. The at least one air amplifier can be in fluid communication with the dielectric window. The at least one air amplifier can operate at a back pressure of at least about 1 in-H.sub.2O and can provide at least about 30 cfm of air.

In one embodiment, a plasma processing device may include a dielectric window, a vacuum chamber, an energy source, and at least one air amplifier. The dielectric window may include a plasma exposed surface and an air exposed surface. The vacuum chamber and the plasma exposed surface of the dielectric window can cooperate to enclose a plasma processing gas. The energy source can transmit electromagnetic energy through the dielectric window and form an elevated temperature region in the dielectric window. The at least one air amplifier can be in fluid communication with the dielectric window. The at least one air amplifier can operate at a back pressure of at least about 1 in-H.sub.2O and can provide at least about 30 cfm of air.

A processing system including an ion source having a plasma chamber to house a plasma, an extraction assembly, disposed along a side of the plasma chamber, and including at least one extraction aperture, and an antenna assembly extending through the plasma chamber. The antenna assembly may include a dielectric enclosure and a plurality of conductive antennas extending through the dielectric enclosure, the conductive antennas having respective gas ports formed therein for delivering a gas into the dielectric enclosure. The processing system may further include a temperature regulation system coupled to the conductive antennas and to the dielectric enclosure for monitoring a temperature of the dielectric enclosure and regulating the gas delivered to the conductive antennas for regulating the temperature of the dielectric enclosure.

Exemplary semiconductor processing methods may include providing a silicon-containing precursor to a processing region of a semiconductor processing chamber. A substrate may be disposed within the processing region of the semiconductor processing chamber. The methods may include forming a plasma of the silicon-containing precursor in the processing region. The plasma may be at least partially formed by an RF power operating at between about 50 W and 1,000 W, at a pulsing frequency below about 100,000 Hz, and at a duty cycle between about 5% and 95%. The methods may include forming a layer of material on the substrate. The layer of material may include a silicon-containing material.

There is provided a decompression processing method for a substrate processing apparatus including a chamber for processing a substrate in an inside thereof, a decompression unit that decompresses the inside of the chamber, and a gas supply that supplies a gas into the inside of the chamber, the method including supplying an additional substance mixable with moisture in a liquid or solid state by the gas supply to the inside of the chamber, forming the moisture into a mixture of the additional substance, and decompressing the inside of the chamber by the decompression unit to remove as a gas the mixture from the inside of the chamber.

A method and apparatus for determining the temperature of a substrate within a processing chamber are described herein. The methods and apparatus described herein utilize an etalon assembly and a heterodyning effect to determine a first temperature of a substrate. The first temperature of the substrate is determined without physically contacting the substrate. A separate temperature sensor also measures a second temperature of the substrate and/or the substrate support at a similar location. The first temperature and the second temperature are utilized to calibrate one of the temperature sensors disposed within the substrate support, a model of the processes performed within the processing chamber, or to adjust a process parameter of the process performed within the processing chamber.