Embodiments described herein relate to apparatus and methods for processing a substrate. In one embodiment, a cluster tool apparatus is provided having a transfer chamber and a pre-clean chamber, a self-assembled monolayer (SAM) deposition chamber, an atomic layer deposition (ALD) chamber, and a post-processing chamber disposed about the transfer chamber. A substrate may be processed by the cluster tool and transferred between the pre-clean chamber, the SAM deposition chamber, the ALD chamber, and the post-processing chamber. Transfer of the substrate between each of the chambers may be facilitated by the transfer chamber which houses a transfer robot.

A deposition method, including providing a channel through a deposition apparatus, feeding precursor vapor into the channel, and depositing material from the precursor vapor onto a substrate on its way through the deposition apparatus by exposing the substrate to the precursor vapor and to alternating photon exposure and shade periods within the channel.

A deposition method, including providing a channel through a deposition apparatus, feeding precursor vapor into the channel, and depositing material from the precursor vapor onto a substrate on its way through the deposition apparatus by exposing the substrate to the precursor vapor and to alternating photon exposure and shade periods within the channel.

Disclosed are a liner assembly for vacuum treatment apparatuses and a vacuum treatment apparatus, wherein the liner assembly for vacuum treatment apparatuses comprises: an annular liner including a sidewall protection ring and a support ring which are interconnected, the outer diameter of the support ring being greater than that of the sidewall protection ring, the annular liner enclosing a treating space; and a gas channel provided in the support ring, the gas channel communicating with the treating space. The liner assembly for vacuum treatment apparatuses offer an improved performance.

The disclosure relates to a substrate processing apparatus, comprising: a first reactor constructed and arranged to process a rack with a plurality of substrates therein; a second reactor constructed and arranged to process a substrate; and, a substrate transfer device constructed and arranged to transfer substrates to and from the first and second reactor. The second reactor may be provided with an illumination system constructed and arranged to irradiate ultraviolet radiation within a range from 100 to 500 nanometers onto a top surface of at least a substrate in the second reactor.

Herein disclosed are systems and methods related to remote delivery systems using solid source chemical bulk fill vessels. The delivery system can include a vapor deposition reactor, two or more bulk fill vessels remote from the vapor deposition reactor, an interconnect line, a line heater, and a gas panel comprising one or more valves. Each bulk fill vessel is configured to hold solid source chemical reactant therein. The bulk fill vessels can each include fluid outlets. The interconnect line can fluidly connect the vapor deposition reactor with each bulk fill vessel. The line heater can heat at least a portion of the interconnect line to at least a minimum line temperature. The one or more valves of the gas panel can switch a flow of vaporized chemical reactant through the interconnect line from being from one fluid outlet to being from another fluid outlet.

An apparatus is provided for coating deposition, particularly by chemical vapour deposition, on three-dimensional glass articles such as bottles. The apparatus lends itself to incorporation in a plant for a continuous production process for glass containers.

An apparatus is provided for coating deposition, particularly by chemical vapour deposition, on three-dimensional glass articles such as bottles. The apparatus lends itself to incorporation in a plant for a continuous production process for glass containers.

Provided herein are low resistance metallization stack structures for logic and memory applications and related methods of fabrication. In some embodiments, thin metal oxynitride or metal nitride nucleation layers are deposited followed by deposition of a pure metal conductor. The nucleation layer is amorphous, which templates large pure metal film grain growth and reduced resistivity. Further, certain embodiments of the methods described below convert most or all of the metal oxynitride nucleation layer to a pure metal layer, further lowering the resistivity.

Disclosed herein is a roll-to-roll long base material surface processing device capable of performing surface processing on a long base material with little occurrence of wrinkling in the long base material at low costs. The surface processing device includes: two can rolls that cool a long resin film transferred in a roll-to-roll manner in a vacuum chamber with a cooling medium circulated therein by wrapping the long resin film around outer circumferences thereof; and surface processing units typified by magnetron sputtering cathodes provided so as to face the outer circumferences of the two can rolls, wherein a second can roll of the two can rolls other than a most upstream first can roll has a gas release mechanism that releases a gas from the outer circumference.