The present disclosure relates to a chemical vapor deposition apparatus and associated methods. In some embodiments, the CVD apparatus has a vacuum chamber and a gas import having a gas import axis through which a process gas is imported into the vacuum chamber and being arranged near an upper region of the vacuum chamber. At least one exhaust port is arranged near a bottom region of the vacuum chamber. The CVD apparatus also has a gas delivery ring with an outlet disposed under the gas import. A pressure near the outlet of the gas delivery ring is smaller than that of the rest of the vacuum chamber.

A component made of a quartz blank is used as a component part of a CVD reactor. At least one cavity of the component is created by selective laser etching, wherein a fluid flows through the at least one cavity. When in use, the component is heated to temperatures in excess of 500° C., and comes into contact with hydrides of the main groups IV, V or VI and/or with organometallic compounds or halogenides of elements of the main groups II, III or V.

A method for operating a substrate processing system includes delivering precursor gas to a chamber using a showerhead that includes a head portion and a stem portion. The head portion includes an upper surface, a sidewall, a lower planar surface, and a cylindrical cavity and extends radially outwardly from one end of the stem portion towards sidewalls of the chamber. The showerhead is connected, using a collar, to an upper surface of the chamber. The collar is arranged around the stem portion. Process gas is flowed into the cylindrical cavity via the stem portion and through a plurality of holes in the lower planar surface to distribute the process gas into the chamber. A purge gas is supplied through slots of the collar into a cavity defined between the head portion and an upper surface of the chamber.

A deposition apparatus includes an upper shower head and a lower shower head within a process chamber, the upper shower head and the lower shower head facing each other, a support structure between the upper shower head and the lower shower head, the support structure being connected to the lower shower head to support a wafer, and a plasma process region between the wafer supported by the support structure and the lower shower head, wherein the lower shower head includes lower holes to jet a lower gas in a direction of the wafer, wherein the upper shower head includes upper holes to jet an upper gas in a direction of the wafer, and wherein the support structure includes through opening portions to discharge a portion of the lower gas jetted through the lower holes to a space between the support structure and the upper shower head.

In a capacitive coupled etch reactor, in which the smaller electrode is predominantly etched, the surface of the larger electrode is increased by a body e.g. a plate, which is on the same electric potential as the larger electrode and which is immersed in the plasma space. A pattern of openings in which plasma may burn is provided in the body so as to control the distribution of the etching effect on a substrate placed on the smaller electrode.

A gas distribution hub for a plasma chamber. The hub has a nozzle including a plurality of inner gas injection passage and a plurality of outer gas injection passages. The first plurality of gas injection passages are angularly spaced-apart arcuate channels at a first radial distance from a center of the hub, and the second plurality of gas injection passages are angularly spaced apart arcuate channels at a different second radial distance from the center of the hub

Embodiments described herein relate to apparatus and techniques for mechanical isolation and thermal insulation in a process chamber. In one embodiment, an insulating layer is disposed between a dome assembly and a gas ring. The insulating layer is configured to maintain a temperature of the dome assembly and prevent thermal energy transfer from the dome assembly to the gas ring. The insulating layer provides mechanical isolation of the dome assembly from the gas ring. The insulating layer also provides thermal insulation between the dome assembly and the gas ring. The insulating layer may be fabricated from a polyimide containing material, which substantially reduces an occurrence of deformation of the insulating layer.

A method for operating a substrate processing system includes delivering precursor gas to a chamber using a showerhead that includes a head portion and a stem portion. The head portion includes an upper surface, a sidewall, a lower planar surface, and a cylindrical cavity and extends radially outwardly from one end of the stem portion towards sidewalls of the chamber. The showerhead is connected, using a collar, to an upper surface of the chamber. The collar is arranged around the stem portion. Process gas is flowed into the cylindrical cavity via the stem portion and through a plurality of holes in the lower planar surface to distribute the process gas into the chamber. A purge gas is supplied through slots of the collar into a cavity defined between the head portion and an upper surface of the chamber.

A gas distribution hub for a plasma chamber. The hub has a nozzle including a plurality of inner gas injection passage and a plurality of outer gas injection passages. The first plurality of gas injection passages are angularly spaced-apart arcuate channels at a first radial distance from a center of the hub, and the second plurality of gas injection passages are angularly spaced apart arcuate channels at a different second radial distance from the center of the hub.

Methods for filling a substrate feature with a carbon gap fill, while leaving a void, are described. Methods comprise flowing a process gas into a high density plasma chemical vapor deposition (HDP-CVD) chamber, the chamber housing a substrate having at least one feature, the process gas comprising a hydrocarbon reactant, generating a plasma, and depositing a carbon film.