Abstract: Chemical vapor deposition methods of forming titanium silicide comprising layers on substrates are disclosed. TiCl4 and at least one silane are first fed to the chamber at or above a first volumetric ratio of TiCl4 to silane for a first period of time. The ratio is sufficiently high to avoid measurable deposition of titanium silicide on the substrate. Alternately, no measurable silane is fed to the chamber for a first period of time. Regardless, after the first period, TiCl4 and at least one silane are fed to the chamber at or below a second volumetric ratio of TiCl4 to silane for a second period of time. If at least one silane was fed during the first period of time, the second volumetric ratio is lower than the first volumetric ratio. Regardless, the second feeding is effective to plasma enhance chemical vapor deposit a titanium silicide comprising layer on the substrate.

Abstract: A first substrate is provided within a chemical vapor deposition chamber. A reactive gas mixture comprising TiCl4 and a silane is provided within the chamber effective to first chemically vapor deposit a titanium silicide comprising layer on the first substrate. After the first deposit, the first substrate is removed from the chamber. After the first deposit, a first cleaning is conducted within the chamber with a chlorine comprising gas. After the first cleaning, a second cleaning is conducted within the chamber with a hydrogen comprising gas. After the second cleaning and after the removing, a titanium silicide comprising layer is chemically vapor deposited over a second substrate within en the chamber using a reactive gas mixture comprising TiCl4 and a silane. Other implementations are disclosed.

Abstract: A first cleaning is conducted on a plasma enhanced chemical vapor deposition chamber at room ambient pressure. After the first cleaning, elemental titanium comprising layers are chemical vapor deposited on a first plurality of substrates within the chamber using at least TiCl4. Thereafter, titanium silicide comprising layers are plasma enhanced chemical vapor deposited on a second plurality of substrates within the chamber using at least TiCl4 and a silane. Thereafter, a second cleaning is conducted on the chamber at ambient room pressure. In one implementation after the first cleaning, an elemental titanium comprising layer is chemical vapor deposited over internal surfaces of the chamber while no semiconductor substrate is received within the chamber. In another implementation, a titanium silicide comprising layer is chemical vapor deposited over internal surfaces of the chamber while no semiconductor substrate is received within the chamber.

Abstract: A method includes removing at least a piece of a deposition chamber liner from a deposition chamber by passing it through a passageway to the deposition chamber through which semiconductor substrates pass into and out of the chamber for deposition processing. A replacement for the removed deposition chamber liner piece is provided into the chamber by passing the replacement through said passageway. A liner apparatus includes a plurality of pieces which when assembled within a selected semiconductor substrate deposition processor chamber are configured to restrict at least a majority portion of all internal wall surfaces which define said semiconductor substrate deposition processor chamber from exposure to deposition material within the chamber. At least some of the pieces are sized for passing completely through a substrates passageway to the chamber through which semiconductor substrates pass into and out of the chamber for deposition processing.

Abstract: A semiconductor substrate processor includes a substrate transfer chamber and a plurality of substrate processing chambers connected therewith. An interfacial structure is received between at least one of the processing chambers and the transfer chamber. The interfacial structure includes a substantially non-metallic, thermally insulative mass of material interposed between the one processing chamber and the transfer chamber. The mass is of sufficient volume to effectively reduce heat transfer from the processing chamber to the transfer chamber than would otherwise occur in the absence of said mass of material. An interfacial structure includes a body having a substrate passageway extending therethrough. The passageway includes walls at least a portion of which are substantially metallic. The body includes material peripheral of the walls which is substantially non-metallic and thermally insulative. The substantially non-metallic material has mounting openings extending at least partially therein.

Abstract: A first cleaning is conducted on a plasma enhanced chemical vapor deposition chamber at room ambient pressure. After the first cleaning, elemental titanium comprising layers are chemical vapor deposited on a first plurality of substrates within the chamber using at least TiCl4. Thereafter, titanium silicide comprising layers are plasma enhanced chemical vapor deposited on a second plurality of substrates within the chamber using at least TiCl4 and a silane. Thereafter, a second cleaning is conducted on the chamber at ambient room pressure. In one implementation after the first cleaning, an elemental titanium comprising layer is chemical vapor deposited over internal surfaces of the chamber while no semiconductor substrate is received within the chamber. In another implementation, a titanium silicide comprising layer is chemical vapor deposited over internal surfaces of the chamber while no semiconductor substrate is received within the chamber.

Abstract: An apparatus and process for atomic layer deposition that minimizes mixing of the chemicals and reactive gases is disclosed. The first precursor and second precursor are only mixed with other chemicals and reactive gases when and where desired by installing and monitoring a dispensing fore-line. Also, independent and dedicated chamber outlets, isolation valves, exhaust fore-lines, and exhaust pumps are provided that are activated for the specific gas when needed.

Abstract: An apparatus and process for atomic layer deposition that minimizes mixing of the chemicals and reactive gases is disclosed. The first precursor and second precursor are only mixed with other chemicals and reactive gases when and where desired by installing and monitoring a dispensing fore-line. Also, independent and dedicated chamber outlets, isolation valves, exhaust fore-lines, and exhaust pumps are provided that are activated for the specific gas when needed.

Abstract: The invention includes a method of forming a layer on a semiconductor substrate that is provided within a reaction chamber. The chamber has at least two inlet ports that terminate in openings. A first material is flowed into the reaction chamber through the opening of a first of the inlet ports. At least a portion of the first material is deposited onto the substrate. The reaction chamber is purged by flowing an inert material into the reaction chamber through the opening of a second of the inlet ports. The inert material passes from the opening and through a distribution head that is positioned within the reaction chamber between the first and second openings. A second material can then be flowed into the chamber through an opening in a third inlet port and deposited onto the substrate. The invention also includes a chemical vapor deposition apparatus.

Abstract: The invention includes a plasma enhanced chemical vapor deposition reactor, and a plasma enhanced chemical vapor deposition process. In one implementation, a plasma enhanced chemical vapor deposition reactor includes a deposition chamber having an electrically conductive RF powered showerhead support electrode. An electrically conductive gas distributing showerhead is mounted to the RF powered showerhead support electrode. A preformed electrically conductive gasket is interposed between the RF powered showerhead support electrode and the gas distributing showerhead.

Abstract: An apparatus and process for atomic layer deposition that minimizes mixing of the chemicals and reactive gases is disclosed. The first precursor and second precursor are only mixed with other chemicals and reactive gases when and where desired by installing and monitoring a dispensing fore-line. Also, independent and dedicated chamber outlets, isolation valves, exhaust fore-lines, and exhaust pumps are provided that are activated for the specific gas when needed.

Abstract: A chemical vapor deposition (CVD) apparatus includes a deposition chamber defined partly by a chamber wall. The chamber wall has an innermost surface inside the chamber and an outermost surface outside the chamber. The apparatus further includes a valve body having a seat between the innermost and outermost surfaces of the chamber wall. The chamber wall can be a lid and the valve can include a portion of the lid as at least a part of the seat. The valve body can include at least a part of a valve housing between the innermost and outermost surfaces of the chamber wall. Such a valve body can even include a portion of the chamber wall as at least part of the valve housing. The deposition apparatus can further include at least a part of a process chemical inlet to the valve body between the innermost and outermost surfaces of the chamber wall. In one example, the chamber wall can form at least a part of the chemical inlet.

Abstract: A chemically sensitive warning apparatus capable of changing colors upon contact with a chemical is disclosed. The apparatus preferably comprises an elongated tape having opposed, first and second major surfaces and warning indicia visible to an individual viewing the first surface to provide visual indication of possible danger or hazardous condition. Mounted to the tape is at least one chemical indicator that is responsive to the presence of at least one chemical by changing colors so as to provide a visual indication of the exposure of the indicator to the chemical. The tape may also include at least one color reference indicia to facilitate interpretation of the color of the chemical indicator when the chemical indicator changes color upon exposure to the chemical.

Abstract: The invention includes a plasma enhanced chemical vapor deposition reactor, and a plasma enhanced chemical vapor deposition process. In one implementation, a plasma enhanced chemical vapor deposition reactor includes a deposition chamber having an electrically conductive RF powered showerhead support electrode. An electrically conductive gas distributing showerhead is mounted to the RF powered showerhead support electrode. A preformed electrically conductive gasket is interposed between the RF powered showerhead support electrode and the gas distributing showerhead.

Abstract: The invention includes a plasma enhanced chemical vapor deposition reactor, and a plasma enhanced chemical vapor deposition process. In one implementation, a plasma enhanced chemical vapor deposition reactor includes a deposition chamber having an electrically conductive RF powered showerhead support electrode. An electrically conductive gas distributing showerhead is mounted to the RF powered showerhead support electrode. A preformed electrically conductive gasket is interposed between the RF powered showerhead support electrode and the gas distributing showerhead.