Abstract: Embodiments of the present invention are directed to the formation of microprobe tips elements having a variety of configurations. In some embodiments tips are formed from the same building material as the probes themselves, while in other embodiments the tips may be formed from a different material and/or may include a coating material. In some embodiments, the tips are formed before the main portions of the probes and the tips are formed in proximity to or in contact with a temporary substrate.

Abstract: Embodiments of the present invention are directed to the formation of microprobe tips elements having a variety of configurations. In some embodiments tips are formed from the same building material as the probes themselves, while in other embodiments the tips may be formed from a different material and/or may include a coating material. In some embodiments, the tips are formed before the main portions of the probes and the tips are formed in proximity to or in contact with a temporary substrate.

Abstract: An electrostatic chuck comprises a dielectric member comprising (i) a first layer comprising a semiconductive material, and (ii) a second layer over the first layer, the second layer comprising an insulative material. The insulative material has a higher electrical resistance than the semiconductive material. An electrode in the dielectric member is chargeable to generate an electrostatic force. The chuck is useful to hold substrates, such as semiconductor wafers, during their processing in plasma processes.

Abstract: To further enhance the chamber material performance of anodized aluminum alloy materials against fluorine and oxygen plasma attack, a ceramic-based surface coating, high purity yttrium oxide coating, is provided on the anodized aluminum alloy parts.

Abstract: A vacuum chamber, such as a semiconductor wafer plasma processing chamber, is heated by use of a ceramic igniter array consisting of a plurality of ceramic igniters positioned in a substrate.

Abstract: An electrostatic chuck has an electrode capable of being electrically charged to electrostatically hold a substrate. A composite layer covers the electrode. The composite layer comprises (1) a first dielectric material covering a central portion of the electrode, and (2) a second dielectric material covering a peripheral portion of the electrode, the second dielectric material having a different composition than the composition of the first dielectric material. The chuck is useful in a plasma process chamber to process substrates, such as semiconductor wafers.

Abstract: An erosion-resistant article for use as a component in plasma process chamber. The erosion-resistant article comprises a support and an oxide coating comprising yttrium, which is disposed over the support. The support and the oxide coating preferably have material compositions that differ from one another in coefficient of thermal expansion by no more than 5×10−6/K. Preferred oxide coating compositions include yttria and yttrium aluminum garnet. Preferred supports include alumina supports and aluminum-silicon carbide supports.

Abstract: A substrate processing chamber has a substrate support, a gas supply, a gas exhaust, a gas energizer, and a wall about the substrate support, the wall having a porous ceramic material at least partially infiltrated with a fluorinated polymer, whereby a substrate on the substrate support may be processed by gas introduced by the gas supply, energized by the gas energizer, and exhausted by the gas exhaust.

Abstract: The invention is embodied in a plasma reactor for processing a semiconductor wafer, the reactor having a gas distribution plate including a front plate in the chamber and a back plate on an external side of the front plate, the gas distribution plate comprising a gas manifold adjacent the back plate, the back and front plates bonded together and forming an assembly. The assembly includes an array of holes through the front plate and communicating with the chamber, at least one gas flow-controlling orifice through the back plate and communicating between the manifold and at least one of the holes, the orifice having a diameter that determines gas flow rate to the at least one hole. In addition, an array of pucks is at least generally congruent with the array of holes and disposed within respective ones of the holes to define annular gas passages for gas flow through the front plate into the chamber, each of the annular gas passages being non-aligned with the orifice.

Abstract: The present invention relates to novel heaters and methods of heating a vacuum chamber, such as a semiconductor wafer plasma processing chamber, using a ceramic igniter array consisting of a plurality of ceramic igniters positioned in a substrate.

Abstract: The invention is embodied in a plasma reactor for processing a semiconductor wafer, the reactor having a gas distribution plate including a front plate in the chamber and a back plate on an external side of the front plate, the gas distribution plate comprising a gas manifold adjacent the back plate, the back and front plates bonded together and forming an assembly. The assembly includes an array of holes through the front plate and communicating with the chamber, at least one gas flow-controlling orifice through the back plate and communicating between the manifold and at least one of the holes, the orifice having a diameter that determines gas flow rate to the at least one hole. In addition, an array of pucks is at least generally congruent with the array of holes and disposed within respective ones of the holes to define annular gas passages for gas flow through the front plate into the chamber, each of the annular gas passages being non-aligned with the orifice.

Abstract: A semiconductor wafer support chuck having small diameter gas distribution ports for heat transfer gas. The diameter ports inhibit plasma ignition in heat transfer gas distribution channels. The ports are less than 20 mils in diameter less than 3 mm in length. The short length of the ports facilitates fabrication of multiple ports of very small diameter. The ports communicate with a gas distribution plenum integrated into the body of the chuck beneath a wafer support surface. The plenum has radial channels and a peripheral groove for distributing heat transfer gas to the wafer support surface.

Abstract: A complexly shaped Si/SiC cermet part including a protective coating deposited on a surface of the cermet part facing the plasma of the reactor. The cermet part is formed by casting a SiC green form and machining the shape into the green form. The green form is incompletely sintered such that it is unconsolidated and shrinks by less than 1% during sintering. Molten silicon is flowed into the voids of the unconsolidated sintered body. Chemical vapor deposition or plasma spraying coats onto the cermet structure a protective film of silicon carbide, boron carbide, diamond, or related carbon-based materials. The part may be configured for use in a plasma reactor, such as a chamber body, showerhead, focus ring, or chamber liner.

Abstract: The invention is embodied in a plasma reactor for processing a semiconductor wafer, the reactor having a gas distribution plate including a front plate in the chamber and a back plate on an external side of the front plate, the gas distribution plate comprising a gas manifold adjacent the back plate, the back and front plates bonded together and forming an assembly. The assembly includes an array of holes through the front plate and communicating with the chamber, at least one gas flow-controlling orifice through the back plate and communicating between the manifold and at least one of the holes, the orifice having a diameter that determines gas flow rate to the at least one hole. In addition, an array of pucks is at least generally congruent with the array of holes and disposed within respective ones of the holes to define annular gas passages for gas flow through the front plate into the chamber, each of the annular gas passages being non-aligned with the orifice.

Abstract: The invention is embodied in a plasma reactor for processing a semiconductor wafer, the reactor having a gas distribution plate including a front plate in the chamber and a back plate on an external side of the front plate, the gas distribution plate comprising a gas manifold adjacent the back plate, the back and front plates bonded together and forming an assembly. The assembly includes an array of holes through the front plate and communicating with the chamber, at least one gas flow-controlling orifice through the back plate and communicating between the manifold and at least one of the holes, the orifice having a diameter that determines gas flow rate to the at least one hole. In addition, an array of pucks is at least generally congruent with the array of holes and disposed within respective ones of the holes to define annular gas passages for gas flow through the front plate into the chamber, each of the annular gas passages being non-aligned with the orifice.

Abstract: A substrate processing chamber has a substrate support, a gas supply, a gas exhaust, a gas energizer, and a wall about the substrate support, the wall having a porous ceramic material at least partially infiltrated with a fluorinated polymer, whereby a substrate on the substrate support may be processed by gas introduced by the gas supply, energized by the gas energizer, and exhausted by the gas exhaust.

Abstract: An electrostatic chuck 55 for holding a substrate 30 comprises an electrostatic member 100 made from a dielectric 115 covering an electrode 105 that is chargeable to electrostatically hold the substrate 30. A base 175 that includes a heater 235 is joined to the electrostatic member 100. The base may be made from a composite material, such as a porous ceramic infiltrated with the metal, and may be joined to the electrostatic member by a bond layer.

Abstract: Apparatus for gas distribution in a semiconductor wafer processing chamber 200 having a roof 228. The roof 228 has a top surface 608 and a bottom surface 312. A recess 314 is disposed within the bottom surface 312 of the roof 228. A gas distribution plate 316 is disposed within the recess 314 and a material layer coating 320 is disposed upon the bottom surfaces 312/500 of the roof 228 and the gas distribution plate 316. The material layer coating 320 and the gas distribution plate 316 each have a plurality of apertures 322/404. The apertures 404 of the gas distribution plate 316 coincide with the apertures 322 in the material layer coating 320. The material layer coating 320 is formed from silicon carbide and most preferably is deposited by chemical vapor deposition (CVD). Both the roof 228 and gas distribution plate 316 are fabricated from silicon carbide.

Abstract: Generally, an electrostatic chuck having a dielectric coating is provided. In one embodiment, an electrostatic chuck includes a support surface, a mounting surface disposed opposite the support surface and at least one side separating the support surface and the mounting surface which defines a support body. One or more conductive members are disposed within the support body to generate an electrostatic attraction between the body and a substrate disposed thereon. A dielectric coating is disposed on the mounting surface of the support body to minimize undesired current leakage therethrough. Optionally, the dielectric coating may be additionally disposed on one or more of the sides and/or the support surface.

Abstract: A chamber 30 for processing a substrate 25 comprises a support 55 comprising a dielectric 60 enveloping an electrode 70. The electrode 70 may be chargeable to electrostatically hold the substrate 25 or may be chargeable to form an energized gas in the chamber 30 to process the substrate 25. A base 130 is below the support 55, and a compliant member 300 is positioned between the support 55 and the base 130. The compliant member 300 may be adapted to alleviate thermal stresses arising from a thermal expansion mismatch between the dielectric 60 and the base 130.