Abstract: A system and method for performing corrective processing of a workpiece is described. The system and method includes receiving a first set of parametric data from a first source that diagnostically relates to at least a first portion of a microelectronic workpiece, and receiving a second set of parametric data from a second source different than the first source that diagnostically relates to at least a second portion of the microelectronic workpiece. Thereafter, a corrective process is generated, and a target region of the microelectronic workpiece is processed by applying the corrective process to the target region using a combination of the first set of parametric data and the second set of parametric data.

Abstract: An apparatus and method for processing a workpiece with a beam is described. The apparatus includes a vacuum chamber having a beam-line for forming a particle beam and treating a workpiece with the particle beam, and a scanner for translating the workpiece through the particle beam. The apparatus further includes a scanner control circuit coupled to the scanner, and configured to control a scan property of the scanner, and a beam control circuit coupled to at least one beam-line component, and configured to control the beam flux of the particle beam according to a duty cycle for switching between at least two different states during processing.

Abstract: An apparatus and method for processing a workpiece with a beam is described. The apparatus includes a vacuum chamber having a beam-line for forming a particle beam and treating a workpiece with the particle beam, and a scanner for translating the workpiece through the particle beam. The apparatus further includes a scanner control circuit coupled to the scanner, and configured to control a scan property of the scanner, and a beam control circuit coupled to at least one beam-line component, and configured to control the beam flux of the particle beam according to a duty cycle for switching between at least two different states during processing.

Abstract: A system and method for performing location specific processing of a workpiece is described. The method includes placing a microelectronic workpiece in a beam processing system, selecting a beam scan size for a beam scan pattern that is smaller than a dimension of the microelectronic workpiece, generating a processing beam, and processing a target region of the microelectronic workpiece by irradiating the processing beam along the beam scan pattern onto the target region within the beam scan size selected for processing the microelectronic workpiece.

Abstract: A system and method for performing corrective processing of a workpiece is described. The system and method includes receiving a first set of parametric data from a first source that diagnostically relates to at least a first portion of a microelectronic workpiece, and receiving a second set of parametric data from a second source different than the first source that diagnostically relates to at least a second portion of the microelectronic workpiece. Thereafter, a corrective process is generated, and a target region of the microelectronic workpiece is processed by applying the corrective process to the target region using a combination of the first set of parametric data and the second set of parametric data.

Abstract: A method for correcting a surface profile on a substrate is described. In particular, the method includes receiving a substrate having a heterogeneous layer composed of a first material and a second material, wherein the heterogeneous layer has an initial upper surface exposing the first material and the second material, and defining a first surface profile across the substrate. The method further includes setting a target surface profile for the heterogeneous layer, selectively removing at least a portion of the first material using a gas cluster ion beam (GCIB) etching process, and recessing the first material beneath the second material, and thereafter, selectively removing at least a portion of the second material to achieve a final upper surface exposing the first material and the second material, and defining a second surface profile, wherein the second surface profile is within a pre-determined tolerance of the target surface profile.

Abstract: A beam processing system and method of operating are described. In particular, the beam processing system includes a beam source having a nozzle assembly that is configured to introduce a primary gas through the nozzle assembly to a vacuum vessel in order to produce a gaseous beam, such as a gas cluster beam, and optionally, an ionizer positioned downstream from the nozzle assembly, and configured to ionize the gaseous beam to produce an ionized gaseous beam. The beam processing system further includes a process chamber within which a substrate is positioned for treatment by the gaseous beam, and a secondary gas source, wherein the secondary gas source includes a secondary gas supply system that delivers a secondary gas, and a secondary gas controller that operatively controls the flow of the secondary gas injected into the beam processing system downstream of the nozzle assembly.

Abstract: Provided is a method of controlling a gas cluster ion beam (GCIB) system for processing structures on a substrate. A GCIB system comprises deflection plates for directing a GCIB towards a substrate, the GCIB system coupled to a substrate scanning device configured to move a substrate in three dimensions. The substrate is exposed to the GCIB while the substrate is being moved by the substrate scanning device. A controller is used to control a set of deflection operating parameters comprising a deflection angle ?, voltage differential of the deflection plates, frequency of the deflection plate power, beam current, substrate distance, pressure in the nozzle, gas flow rate in the process chamber, separation of beam burns, duration of the bean burn, and/or duty cycle of the beam deflector output.

Abstract: Disclosed are an apparatus, system, and method for scanning a substrate or other workpiece through a gas-cluster ion beam (GCIB), or any other type of ion beam. The workpiece scanning apparatus is configured to receive and hold a substrate for irradiation by the GCIB and to scan it through the GCIB in two directions using two movements: a reciprocating fast-scan movement, and a slow-scan movement. The slow-scan movement is actuated using a servo motor and a belt drive system, the belt drive system being configured to reduce the failure rate of the workpiece scanning apparatus.

Abstract: A method for patterning a substrate is described. The method includes receiving a substrate having a patterned layer, wherein the patterned layer defines a first mandrel pattern, and wherein a first material layer of a first composition is conformally deposited over the first mandrel pattern. The method further includes partially removing the first material layer using a first gas cluster ion beam (GCIB) etching process to expose a top surface of the first mandrel pattern, open a portion of the first material layer at a bottom region adjacent a feature of the first mandrel pattern, and retain a remaining portion of the first material layer on sidewalls of the first mandrel pattern; and selectively removing the first mandrel pattern using one or more etching processes to leave a second mandrel pattern comprising the remaining portion of the first material layer that remained on the sidewalls of the first mandrel pattern.

Abstract: Techniques disclosed herein a method and system for conditioning a polymeric layer on a substrate to enable adhesion of a metal layer to the polymeric layer. Techniques may include conditioning the polymeric layer with nitrogen-containing plasma to generate a nitride layer on the surface of the polymeric layer. In another embodiment, the conditioning may include depositing a CuN layer using a lower power copper sputtering process in a nitrogen rich environment. Following the condition process, a higher power copper deposition or sputtering process may be used to deposit copper onto the polymeric layer with good adhesion properties.

Abstract: A nozzle assembly used for performing gas cluster ion beam (GCIB) etch processing of various materials is described. In particular, the nozzle assembly includes two or more conical nozzles that are aligned such that they are both used to generate the same GCIB. The first conical nozzle may include the throat that initially forms the GCIB and the second nozzle may form a larger conical cavity that may be appended to the first conical nozzle. A transition region may be disposed between the two conical nozzles that may substantially cylindrical and slightly larger than the largest diameter of the first conical nozzle.

Abstract: A method and system for performing gas cluster ion beam (GCIB) etch processing of various materials is described. In particular, the GCIB etch processing includes setting one or more GCIB properties of a GCIB process condition for the GCIB to achieve one or more target etch process metrics. Furthermore, the GCIB etch processing utilizes Si-containing and/or Ge-containing etchants. Further yet, the GCIB etch processing facilitates etching Si-containing material, Ge-containing material, and metal-containing material.

Abstract: A method of assembling a nozzle/skimmer module includes coupling a nozzle assembly and skimmer cartridge assembly in a rigid tandem configuration to more accurately control the formation of the Gas Cluster Ion Beam (GCIB). The nozzle/skimmer module is pre-aligned before installation in a production GCIB processing system to more accurately position the GCIB.

Abstract: A method and system for performing gas cluster ion beam (GCIB) etch processing of various materials is described. In particular, the GCIB etch processing includes using one or more molecular beams to optimize pressure at localized regions of the ion beam.

Abstract: A gas cluster ion beam (GCIB) etching method for adjusting a fin height in finFET devices is described. The method includes providing a substrate having a fin structure and a gap-fill material layer completely overlying the fin structure and filling the regions between each fin of the fin structure, wherein each fin includes a cap layer formed on a top surface thereof, and planarizing the gap-fill material layer until the cap layer is exposed on at least one fin of the fin structure. Additionally, the method includes setting a target fin height for the fin structure, wherein the fin height measured from an interface between the cap layer and the fin structure, and exposing the substrate to a GCIB and recessing the gap-fill material layer relative to the cap layer until the target fin height is substantially achieved.

Abstract: A method of modifying an upper layer of a workpiece using a gas cluster ion beam (GCIB) is described. The method includes collecting parametric data relating to an upper layer of a workpiece, and determining a predicted systematic error response for applying a GCIB to the upper layer to alter an initial profile of a measured attribute by using the parametric data. Additionally, the method includes identifying a target profile of the measured attribute, directing the GCIB toward the upper layer of the workpiece, and spatially modulating an applied property of the GCIB, based at least in part on the predicted systematic error response and the parametric data, as a function of position on the upper layer of the workpiece to achieve the target profile of the measured attribute.

Abstract: Disclosed are an apparatus, system, and method for scanning a substrate or other workpiece through a gas-cluster ion beam (GCIB), or any other type of ion beam. The workpiece scanning apparatus is configured to receive and hold a substrate for irradiation by the GCIB and to scan it through the GCIB in two directions using two movements: a reciprocating fast-scan movement, and a slow-scan movement. The slow-scan movement is actuated using a servo motor and a belt drive system, the belt drive system being configured to reduce the failure rate of the workpiece scanning apparatus.

Abstract: A method of forming a thin film on a substrate is described. The method comprises providing a substrate in a reduced-pressure environment, and generating a gas cluster ion beam (GCIB) in the reduced-pressure environment from a pressurized gas mixture. A beam acceleration potential and a beam dose are set to achieve a thickness of the thin film ranging up to about 300 angstroms and to achieve a surface roughness of an upper surface of the thin film that is less than about 20 angstroms. The GCIB is accelerated according to the beam acceleration potential, and the accelerated GCIB is irradiated onto at least a portion of the substrate according to the beam dose. By doing so, the thin film is grown on the at least a portion of the substrate to achieve the thickness and the surface roughness.

Abstract: Disclosed are an apparatus, system, and method for scanning a substrate or other workpiece through a gas-cluster ion beam (GCIB), or any other type of ion beam. The workpiece scanning apparatus is configured to receive and hold a substrate for irradiation by the GCIB and to scan it through the GCIB in two directions using two movements: a reciprocating fast-scan movement, and a slow-scan movement. The slow-scan movement is actuated using a servo motor and a belt drive system, the belt drive system being configured to reduce the failure rate of the workpiece scanning apparatus. The apparatus further includes shields and other features for reducing process contamination resulting from scattering of the GCIB from the scanning apparatus.