A semiconductor device manufacturing method comprising loading a substrate into a substrate treatment apparatus, performing a deposition process on the substrate, and cleaning the substrate treatment apparatus. The substrate treatment apparatus includes a housing defining a treatment area in which the deposition process is performed, a gas supply supplying a first process gas at a flow rate of 1000 sccm to 15000 sccm and supplying a second process gas, a remote plasma supply connected to the gas supply, generating a first process plasma and a second process plasma by applying RF power to plasma-process the first process gas and the second process gas, and a shower head installed in the housing to supply the first process plasma and the second process plasma to the treatment area. The second process plasma cleans a membrane material deposited on an inner wall of the housing.

Exemplary semiconductor processing systems may include a remote plasma source. The remote plasma source may include a first plasma block segment defining an inlet to an internal channel of the first plasma block segment. The first plasma block segment may also define a cooling channel between the internal channel of the first plasma block segment and a first exterior surface of the first plasma block segment. The remote plasma source may include a second plasma block segment defining an outlet from an internal channel of the second plasma block segment. The second plasma block segment may also define a cooling channel between the internal channel of the second plasma block segment and a first exterior surface of the second plasma block segment. The systems may include a semiconductor processing chamber defining an inlet fluidly coupled with the outlet from the remote plasma source.

Methods of cleaning a substrate support comprise: introducing a cleaning gas into a processing chamber containing the substrate support; applying a radio frequency (RF) power to a remote plasma source that is in fluid communication with the processing chamber to establish a reactive etching plasma from the cleaning gas in the processing chamber; reacting deposits on the substrate support with the reactive etching plasma to form a by-products phase; and evacuating the by-products phase from the processing chamber.

There is provided a plasma processing device comprising: a chamber; an upper electrode; a showerhead provided below the upper electrode, which divides an internal space of the chamber into a first space between the upper electrode and the showerhead and a second space below the showerhead, and provides a plurality of introduction ports for introducing a gas into the second space and a plurality of openings penetrating the showerhead so that the first space and the second space are in communication with each other; a substrate support portion configured to support a substrate in the second space; an ion trap provided between the upper electrode and the showerhead, wherein the ion trap provides a plurality of through holes arranged not to align with the plurality of openings of the showerhead; a first gas supply portion configured to supply a gas to a region in the first space between the upper electrode and the ion trap; a second gas supply portion configured to supply the showerhead with a gas to be introduced from the plurality of introduction ports into the second space; a power source configured to produce a power for generating plasma, and connected to the upper electrode; and a switch configured to switchably connect the showerhead to one of a ground and the upper electrode.

Techniques described herein relate to methods, apparatus, and systems for promoting adhesion between a substrate and a metal-containing photoresist. For instance, the method may include receiving the substrate in a reaction chamber, the substrate having a first material exposed on its surface, the first material including a silicon-based material and/or a carbon-based material; generating a plasma from a plasma generation gas source that is substantially free of silicon, where the plasma includes chemical functional groups; exposing the substrate to the plasma to modify the surface of the substrate by forming bonds between the first material and chemical functional groups from the plasma; and depositing the metal-containing photoresist on the modified surface of the substrate, where the bonds between the first material and the chemical functional groups promote adhesion between the substrate and the metal-containing photoresist.

A method for removing residue deposits from a reaction chamber includes supplying a cleaning gas into the reaction chamber via direct delivery from a remote plasma source (RPS). The cleaning gas forms a plurality of gas flow streamlines within the reaction chamber. Each of the streamlines originates at an injection point for receiving the cleaning gas and terminates at a chamber pump port coupled to a fore line for evacuating the cleaning gas. A flow characteristic of the cleaning gas is modified to redirect at least a portion of the gas flow streamlines to circulate in proximity to an inner perimeter of the reaction chamber to remove the residue deposits or to enhance the diffusion of cleaning species to surfaces to be cleaned. The inner perimeter is disposed along one or more vertical surfaces of the reaction chamber that are orthogonal to a horizontal surface including the injection point.

An apparatus for atomic scale processing is provided. The apparatus may include a reactor and an inductively coupled plasma source. The reactor may have inner and outer surfaces such that a portion of the inner surfaces define an internal volume of the reactor. The internal volume of the reactor may contain a fixture assembly to support a substrate wherein the partial pressure of each background impurity within the internal volume may be below 10.sup.−6 Torr to reduce the role of said impurities in surface reactions during atomic scale processing.

An apparatus for forming a plasma may include one or more coupling ports to accept and RF current. The apparatus may additionally include a receptacle to accommodate one or more gases, in which the receptacle is oriented along a first axis. The apparatus may additionally include an RF coupling structure, oriented in a plane and substantially surrounding the receptacle, the RF coupling structure can be configured to conduct an RF current to bring about formation of the plasma within the receptacle. The apparatus may further include one or more linkages, coupled to the RF coupling structure, which may permit the plane of the RF coupling structure to pivot about a second axis so as to tilt the plane of the RF coupling structure toward the first axis.

Various embodiments include apparatuses, systems, and methods for using a remote-plasma cleaning system with a directional-flow device for concurrently cleaning multiple processing stations in a processing tool used in the semiconductor and allied fields. In one example, an apparatus used to perform a remote-plasma clean (RPC) in a multi-station process chamber is disclosed and includes an RPC directional-flow device that is to be coupled between an RPC reactor and the process chamber. The RPC directional-flow device includes a number of ramped gas-diversion areas to direct at least a radical species generated by the RPC reactor to a separate one of the processing stations. An incoming cleaning-gas diversion hub is to receive the radical species and distribute at least the species substantially-uniformly to each of the of the ramped gas-diversion areas. Other apparatuses, systems, and methods are disclosed.

A method of performing pulsed remote plasma etching includes arranging a substrate in a processing chamber configured to perform pulsed remote plasma etching, setting at least one process parameter of the processing chamber, supplying at least one gas mixture to an upper chamber region of the processing chamber, supplying, in an ON period, a first voltage to coils arranged around the upper chamber region to energize the at least one gas mixture and generate plasma within the upper chamber region of the processing chamber, turning off the first voltage in an OFF period to discontinue generating plasma within the upper chamber region of the processing chamber, and alternating between supplying the first voltage in the ON period and turning off the first voltage in the OFF period to generate pulsed remote plasma within the upper chamber region of the processing chamber.