An exemplary embodiment of the present invention provides a substrate treating apparatus, including: a chamber having an inner space; a shower head for partitioning the inner space into an upper first zone and a lower second zone, and formed with a plurality of through holes; a support unit for supporting a substrate in the second zone; a gas supply unit for supplying gas to the first zone; a plasma source for forming a plasma in the first zone by exciting the gas; and an adsorption plate coupled to the shower head, in which a surface of the adsorption plate is provided with a material that adsorbs radicals contained in the plasma.

The present invention provides a substrate treating method, including: a first treatment operation of treating the substrate by using first plasma generated by exciting first gas; and a second treatment operation of treating the substrate by using second plasma generated by exciting second gas different from the first gas.

An ion beam etching method includes applying a positive voltage for extracting ions into a vacuum container to a first electrode, under a first condition where irradiation of a substrate with an ion beam is blocked off by a shutter, generating plasma in an internal space under the first condition, forming the ion beam by forming, under the first condition, a second condition where a positive voltage is applied to the first electrode and a negative voltage is applied to a second electrode, and moving the shutter and processing the substrate by irradiating the substrate with the ion beam.

Ion species are supplied to a workpiece comprising a pattern layer over a substrate. A material layer is deposited on the pattern layer using an implantation process of the ion species. In one embodiment, the deposited material layer has an etch selectivity to the pattern layer. In one embodiment, a trench is formed on the pattern layer. The trench comprises a bottom and a sidewall. The material layer is deposited into the trench using the ion implantation process. The material layer is deposited on the bottom of the trench in a direction along the sidewall.

A substrate processing apparatus using plasma capable of efficiently controlling the selectivity ratio of a silicon layer and an oxide layer is provided. The substrate processing apparatus comprises a first space disposed between an electrode and an ion blocker; a second space disposed between the ion blocker and a shower head; a processing space under the shower head for processing a substrate; a first supply hole for providing a first gas for generating plasma to the first space; a second supply hole for providing a second gas to be mixed with an effluent of the plasma to the second space; and a first coating layer formed on a first surface of the shower head facing the second space, not formed on a second surface of the shower head facing the processing space, and containing nickel.

A fastening assembly for fastening a beam blocker to an extraction plate, the fastening assembly including a mounting pin having a shaft portion, a base portion at a first end of the shaft portion, and a head portion at a second end of the shaft portion, a centering sleeve radially surrounding the shaft portion and axially abutting the base portion, the centering sleeve being radially compressible between the shaft portion and the extraction plate and between the shaft portion and the beam blocker, an annular spacer surrounding the centering sleeve and axially abutting the beam blocker, with the centering sleeve extending partially into the spacer, and a latching cap surrounding the shaft portion and axially abutting the spacer, with the shaft portion extending through a through hole of the latching cap, the through hole being smaller than the head portion in a direction perpendicular to an axis of mounting pin.

A method of selectively etching silicon nitride from a substrate comprising a silicon nitride layer and a silicon oxide layer includes flowing a fluorine-containing gas into a plasma generation region of a substrate processing chamber and applying energy to the fluorine-containing gas to generate a plasma in the plasma generation region. The plasma comprises fluorine radicals and fluorine ions. The method also includes filtering the plasma to provide a reactive gas having a higher concentration of fluorine radicals than fluorine ions and flowing the reactive gas into a gas reaction region of the substrate processing chamber. The method also includes exposing the substrate to the reactive gas in the gas reaction region of the substrate processing chamber. The reactive gas etches the silicon nitride layer at a higher etch rate than the reactive gas etches the silicon oxide layer.

Embodiments disclosed herein generally include an apparatus for radical-based deposition of dielectric films. The apparatus includes a processing chamber, a radical source coupled to the processing chamber, a substrate support disposed in the processing chamber, and a dual-channel showerhead disposed between the radical source and the substrate support. The dual-channel showerhead includes a plurality of tubes and an internal volume surrounding the plurality of tubes. The plurality of tubes and the internal volume are surrounded by one or more annular channels embedded in the dual-channel showerhead. The dual-channel showerhead further includes a first inlet connected to the one or more channels and a second inlet connected to the internal volume. The processing chamber may be a PECVD chamber, and the apparatus is capable of performing a cyclic process (alternating radical based CVD and PECVD).

An apparatus for treating a wafer is provided. The apparatus includes a platen, a chamber, an etch gas supplier and a tilting mechanism. The chamber has at least one aperture at least partially facing to the platen. The etch gas supplier is fluidly connected to the chamber. The tilting mechanism is coupled with the platen for allowing the platen to have at least one first degree of freedom to tilt relative to the aperture of the chamber.

A method of etching a substrate that includes: generating a first plasma from a first gas flowing into a first chamber by applying a first power pulse to a first electrode located in the first chamber over a first time duration; and forming a recess in a substrate located in a second chamber, the forming including: providing radicals from the first chamber into the second chamber; applying a plurality of second power pulses to a second electrode located in the second chamber during a second time duration to generate a second plasma in the second chamber from a second gas flowing into the second chamber, the first chamber being pressurized higher than the second chamber; and applying a plurality of third power pulses to a third electrode located in the second chamber during a third time duration to accelerate ions of the second plasma.