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 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 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: 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.

Abstract: Disclosed is a multi-nozzle and skimmer assembly for introducing a process gas mixture, or multiple process gases mixtures, in a gas cluster ion beam (GCIB) system, and associated methods of operation to grow, modify, deposit, or dope a layer upon a substrate. The multiple nozzle and skimmer assembly includes at least two nozzles arranged in mutual close proximity to at least partially coalesce the gas cluster beams emitted therefrom into a single gas cluster beam and/or angled to converge each beam toward a single intersecting point to form a set of intersecting gas cluster beams, and to direct the single and/or intersecting gas cluster beam into a gas skimmer.

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.

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 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 pre-aligned multi-output nozzle/skimmer (PMNS) module includes a pre-aligned nozzle assembly having at least two nozzles and a pre-aligned skimmer subassembly. The PMNS module can be pre-aligned to more accurately position a Multi-Beam Gas Cluster Ion Beam (MBGCIB), and to more accurately control the formation of the multi-beam gas clusters of a pre-aligned MBGCIB.

Abstract: Disclosed are methods of operation to grow, modify, deposit, or dope a layer upon a substrate using a multi-nozzle and skimmer assembly for introducing a process gas mixture, or multiple process gases mixtures, in a gas cluster ion beam (GCIB) system. Also disclosed is a method of forming a shallow trench isolation (STI) structure on a substrate, for example, an SiO2 STI structure, using a multiple nozzle system with two separate gas supplies, for example providing a silicon-containing gas and an oxygen-containing gas.

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 gas cluster ion beam (GCIB) processing system using multiple nozzles for forming and emitting at least one GCIB and methods of operating thereof are described. The GCIB processing system may be configured to treat a substrate, including, but not limited to, doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon. Furthermore, the GCIB processing system may be operated to produce a first GCIB and a second GCIB, and to irradiate a substrate simultaneously and/or sequentially with the first GCIB and second GCIB.

Abstract: The pre-aligned nozzle/skimmer module includes an internal pre-aligned nozzle assembly and internal pre-aligned skimmer cartridge assembly to more accurately control the formation of the Gas Cluster Ion Beam (GCIB). The nozzle/skimmer module can be pre-aligned to more accurately position the GCIB. The pre-aligned nozzle/skimmer module more accurately controls the formation of the gas clusters of a pre-aligned Gas Cluster Ion Beam (GCIB).

Abstract: A gas cluster ion beam (GCIB) processing system using multiple nozzles for forming and emitting at least one GCIB and methods of operating thereof are described. The GCIB processing system may be configured to treat a substrate, including, but not limited to, doping, growing, depositing, etching, smoothing, amorphizing, or modifying a layer thereupon. Furthermore, the GCIB processing system may be operated to produce a first GCIB and a second GCIB, and to irradiate a substrate simultaneously and/or sequentially with the first GCIB and second GCIB.

Abstract: Disclosed is a multi-nozzle and skimmer assembly for introducing a process gas mixture, or multiple process gases mixtures, in a gas cluster ion beam (GCIB) system, and associated methods of operation to grow, modify, deposit, or dope a layer upon a substrate. The multiple nozzle and skimmer assembly includes at least two nozzles arranged in mutual close proximity to at least partially coalesce the gas cluster beams emitted therefrom into a single gas cluster beam and/or angled to converge each beam toward a single intersecting point to form a set of intersecting gas cluster beams, and to direct the single and/or intersecting gas cluster beam into a gas skimmer.

Abstract: Disclosed are methods of operation to grow, modify, deposit, or dope a layer upon a substrate using a multi-nozzle and skimmer assembly for introducing a process gas mixture, or multiple process gases mixtures, in a gas cluster ion beam (GCIB) system. Also disclosed is a method of forming a shallow trench isolation (STI) structure on a substrate, for example, an SiO2 STI structure, using a multiple nozzle system with two separate gas supplies, for example providing a silicon-containing gas and an oxygen-containing gas.

Abstract: A method and apparatus 300 for better controlling scanning of a workpiece 330 through an ion beam path 306 provide for mounting a workpiece 330 on an elongated member, partially repetitively rotating the elongated member 500 around a point of rotation 368 to make repetitive scans of the workpiece 330 along and arcuate path 504 and bending the elongated member 500 at a joint 322 to move the one and out of the ion beam path 306 to facilitate attachment and removal of individual workpieces 330. A motor 315 used for the rotating may be suspended within a partial vacuum enclosure 304 against gravity for raising and lowering the elongated member and 500 a workpiece 306 for linear vertical scanning.

Abstract: A method and apparatus 300 for better controlling scanning of a workpiece 330 through an ion beam path 306 provide for mounting a workpiece 330 on an elongated member, partially repetitively rotating the elongated member 500 around a point of rotation 368 to make repetitive scans of the workpiece 330 along and arcuate path 504 and bending the elongated member 500 at a joint 322 to move the one and out of the ion beam path 306 to facilitate attachment and removal of individual workpieces 330. A motor 315 used for the rotating may be suspended within a partial vacuum enclosure 304 against gravity for raising and lowering the elongated member and 500 a workpiece 306 for linear vertical scanning.

Abstract: Numerous studies suggest that the current popular designs of coronary stents are functionally equivalent and suffer a 16 to 22 percent rate of restenosis. Although the use of coronary stents is growing, the benefits of their use remain controversial in certain clinical situations or indications due to their potential complications. The application of gas cluster ion beam (GCIB) surface modification such as smoothing or cleaning appears to reduce these complications and lead to genuine cost savings and an improvement in patient quality of life. The present invention is directed to the use of GCIB surface modification to overcome prior problems of thrombosis and restenosis. The atomic level surface smoothing of stents utilizing GCIB substantially reduces undesirable surface micro-roughness in medical coronary stents.

Abstract: Numerous studies suggest that the current popular designs of coronary stents are functionally equivalent and suffer a 16 to 22 percent rate of restenosis. Although the use of coronary stents is growing, the benefits of their use remain controversial in certain clinical situations or indications due to their potential complications. The application of gas cluster ion beam (GCIB) surface modification such as smoothing or cleaning appears to reduce these complications and lead to genuine cost savings and an improvement in patient quality of life. The present invention is directed to the use of GCIB surface modification to overcome prior problems of thrombosis and restenosis. The atomic level surface smoothing of stents utilizing GCIB substantially reduces undesirable surface micro-roughness in medical coronary stents.