Embodiments of process kits are provided herein. In some embodiments, a process kit, includes: a deposition ring configured to be disposed on a substrate support, the deposition ring comprising: an annular band having an upper surface and a lower surface, the lower surface including a step between a radially inner portion and a radially outer portion, the step extending downward from the radially inner portion to the radially outer portion; an inner lip extending upwards from the upper surface of the annular band and adjacent an inner surface of the annular band, and wherein an outer surface of the inner lip extends radially outward and downward from an upper surface of the inner lip to the upper surface of the annular band; a channel disposed radially outward of the annular band; and an outer lip extending upwardly and disposed radially outward of the channel.

A substrate processing apparatus includes a processing chamber where a substrate support on which a substrate is placed and a target holder configured to hold a target are disposed, a freezing device disposed with a gap with respect to a bottom surface of the substrate support and having a chiller and a cold heat medium laminated on the chiller, and a rotating device configured to rotate the substrate support. The substrate processing apparatus further includes a first elevating device configured to raise and lower the substrate support, a coolant channel formed in the chiller to supply a coolant to the gap, and a cold heat transfer material disposed in the gap and being in contact with the substrate support and the cold heat medium so as to transfer heat therebetween.

The present disclosure provides a thin-film-deposition equipment with shielding device, which includes a reaction chamber, a carrier and a shielding device. The shielding device includes a first-carry arm, a second-carry arm, a first-shield member, a second-shield member and a driver. The driver interconnects the first-carry arm and the second first-carry arm, for driving and swinging the first-shield member and the second-shield member to move in opposite directions via the first-carry arm and the second first-carry arm. During a cleaning process, the driver swings the shield members toward each other into a shielding state for covering the carrier, such that to prevent polluting the carrier during the process of cleaning the thin-film-deposition equipment.

Certain examples described herein relate to a sputter deposition apparatus including a guiding member to guide a substrate in a conveyance direction, a plasma source to generate a plasma, and a magnet arrangement. The magnet arrangement is configured to confine the plasma within the apparatus to a pre-treatment zone, within which the substrate is exposed to the plasma in use. The magnet arrangement is also configured to confine the plasma within the apparatus to a sputter deposition zone, located after the pre-treatment zone in the conveyance direction, to provide for sputter deposition of a target material to the substrate in use. The pre-treatment and sputter deposition zones are disposed about the guiding member.

Certain examples described herein relate to a sputter deposition apparatus including a guiding member to guide a substrate in a conveyance direction, a plasma source to generate a plasma, and a magnet arrangement. The magnet arrangement is configured to confine the plasma within the apparatus to a pre-treatment zone, within which the substrate is exposed to the plasma in use. The magnet arrangement is also configured to confine the plasma within the apparatus to a sputter deposition zone, located after the pre-treatment zone in the conveyance direction, to provide for sputter deposition of a target material to the substrate in use. The pre-treatment and sputter deposition zones are disposed about the guiding member.

A sputter deposition apparatus including: a plasma generation arrangement arranged to provide single plasma for sputter deposition of target material within a sputter deposition zone; a conveyor system arranged to convey a substrate through the sputter deposition zone in a conveyance direction; and one or more target support assemblies arranged to support one or more targets in the sputter deposition zone so as to provide for sputter deposition of the target material on the substrate utilising the plasma such that as the substrate is conveyed through the sputter deposition zone in use there is deposited: a first stripe on the substrate; and a second stripe on the substrate. The first stripe includes at least one of: a different density of the target material or a different composition of the target material than the second stripe.

A sputter deposition apparatus including: a plasma generation arrangement arranged to provide single plasma for sputter deposition of target material within a sputter deposition zone; a conveyor system arranged to convey a substrate through the sputter deposition zone in a conveyance direction; and one or more target support assemblies arranged to support one or more targets in the sputter deposition zone so as to provide for sputter deposition of the target material on the substrate utilising the plasma such that as the substrate is conveyed through the sputter deposition zone in use there is deposited: a first stripe on the substrate; and a second stripe on the substrate. The first stripe includes at least one of: a different density of the target material or a different composition of the target material than the second stripe.

An attachment system and method for optical parts for applying treatments and deposits on at least one surface of said parts without sparse zones on said surface. The system includes an optical part holder in the form of a flange provided with two branches connected at respective first branch ends thereof by a spring link and provided at respective second branch ends thereof with facing tabs and means for bringing said tabs together suited for tightening the branches on an edge of said parts. The method includes a step of positioning an optical part holder in the form of a flange on the edge of said optical part, where a front surface of said flange is positioned recessed from the surface to be treated or flush with the surface to be treated and a step of tightening the flange on the edge of said optical part.

Methods and apparatus for processing a substrate are provided herein. For example, a cooling apparatus for use with a substrate support of a processing chamber comprises a heat exchanger, a manifold assembly comprising a first input configured to connect to an output of the heat exchanger, a second input configured to connect to a first coolant supply configured to supply a first coolant, a first output configured to connect to the substrate support of the processing chamber, and a second output configured to connect to an input of the heat exchanger, a gas input configured to connect to a second coolant supply that is configured to supply a second coolant that is different from the first coolant to the substrate support, a first three-way valve connected between the first output of the manifold assembly and the substrate support and connected between the gas input and the substrate support, and a controller configured to control supplying one of the first coolant or the second coolant during operation.

Methods and apparatus for processing a substrate are provided herein. For example, a cooling apparatus for use with a substrate support of a processing chamber comprises a heat exchanger, a manifold assembly comprising a first input configured to connect to an output of the heat exchanger, a second input configured to connect to a first coolant supply configured to supply a first coolant, a first output configured to connect to the substrate support of the processing chamber, and a second output configured to connect to an input of the heat exchanger, a gas input configured to connect to a second coolant supply that is configured to supply a second coolant that is different from the first coolant to the substrate support, a first three-way valve connected between the first output of the manifold assembly and the substrate support and connected between the gas input and the substrate support, and a controller configured to control supplying one of the first coolant or the second coolant during operation.