Patent application number | Description | Published |
20090200460 | ETHANE IMPLANTATION WITH A DILUTION GAS - To implant a carbon-containing species, a gas containing carbon is ionized in the ion chamber. The ionization of this gas will typically produce a number of ionized species. However, many of these resulting ionized species are not beneficial to the desired implant, as they contain only non-carbon atoms. These species must be eliminated before the implantation, leaving only carbon-based species. However, the current of the desired species may be low, thereby requiring extra energy or time to implant the desired dosage of carbon into a substrate. This can be improved through the use of a second gas. This second gas is used to dilute the primary carbon-containing gas to be ionized in the ion chamber. By incorporating this dilution gas, more of the resulting ionized species are beneficial to the carbon implantation. | 08-13-2009 |
20100041219 | USJ TECHNIQUES WITH HELIUM-TREATED SUBSTRATES - A method of using helium to create ultra shallow junctions is disclosed. A pre-implantation amorphization using helium has significant advantages. For example, it has been shown that dopants will penetrate the substrate only to the amorphous-crystalline interface, and no further. Therefore, by properly determining the implant energy of helium, it is possible to exactly determine the junction depth. Increased doses of dopant simply reduce the substrate resistance with no effect on junction depth. Furthermore, the lateral straggle of helium is related to the implant energy and the dose rate of the helium PAI, therefore lateral diffusion can also be determined based on the implant energy and dose rate of the helium PAI. Thus, dopant may be precisely implanted beneath a sidewall spacer, or other obstruction. | 02-18-2010 |
20100084577 | TECHNIQUES FOR ION IMPLANTATION OF MOLECULAR IONS - Techniques for ion implantation of molecular ions are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus for ion implantation comprising an ion implanter for implanting a target material with a molecular ion at a predetermined temperature to improve at least one of strain and amorphization of the target material, wherein the molecular ion is generated in-situ within an ion source. | 04-08-2010 |
20100084583 | REDUCED IMPLANT VOLTAGE DURING ION IMPLANTATION - A method for ion implantation is disclosed which includes decreasing the implant energy level as the implant process is ongoing. In this way, either a box-like profile or a profile with higher retained dose can be achieved, enabling enhanced activation at the same junction depth. In one embodiment, the initial implant energy is used to implant about 25% of the dose. The implant energy level is then reduced and an additional 50% of the dose is implanted. The implant energy is subsequently decreased again and the remainder of the dose is implanted. The initial portion of the dose can optionally be performed at cold, such as cryogenic temperatures, to maximize amorphization of the substrate. | 04-08-2010 |
20110033998 | OPTIMIZED HALO OR POCKET COLD IMPLANTS - An improved method of performing pocket or halo implants is disclosed. The amount of damage and defects created by the halo implant degrades the performance of the semiconductor device, by increasing leakage current, decreasing the noise margin and increasing the minimum gate voltage. The halo or packet implant is performed at cold temperature, which decreases the damage caused to the crystalline structure and improves the amorphization of the crystal. The use of cold temperature also allows the use of lighter elements for the halo implant, such as boron or phosphorus. | 02-10-2011 |
20110034013 | Low Temperature Ion Implantation - A method of processing to a substrate while minimizing cost and manufacturing time is disclosed. The implantation of the source and drain regions of a semiconductor device are performed at low temperatures, such as below 273° K. This low temperature implant reduces the structural damage caused by the impacting ions. Subsequently, the implanted substrate is activated using faster forms of annealing. By performing the implant at low temperatures, the damage to the substrate is reduced, thereby allowing a fast anneal to be used to activate the dopants, while eliminating the majority of the defects and damage. Fast annealing is less expensive than conventional furnace annealing, and can achieve higher throughput at lower costs. | 02-10-2011 |
20110034014 | COLD IMPLANT FOR OPTIMIZED SILICIDE FORMATION - A method of applying a silicide to a substrate while minimizing adverse effects, such as lateral diffusion of metal or “piping” is disclosed. The implantation of the source and drain regions of a semiconductor device are performed at cold temperatures, such as below 0° C. This cold implant reduces the structural damage caused by the impacting ions. Subsequently, a silicide layer is applied, and due to the reduced structural damage, metal diffusion and piping into the substrate is lessened. In some embodiments, an amorphization implant is performed after the implantation of dopants, but prior to the application of the silicide. By performing this pre-silicide implant at cold temperatures, similar results can be obtained. | 02-10-2011 |
20110104618 | SELF-ALIGNED MASKING FOR SOLAR CELL MANUFACTURE - Various methods of utilizing the physical and chemical property differences between amorphized and crystalline silicon are used to create masks that can be used for subsequent implants. In some embodiments, the difference in film growth between amorphous and crystalline silicon is used to create the mask. In other embodiments, the difference in reflectivity or light absorption between amorphous and crystalline silicon is used to create the mask. In other embodiments, differences in the characteristics of doped and undoped silicon is used to create masks. | 05-05-2011 |
20110253902 | MOLECULAR ION GENERATION - An apparatus that generates molecular ions and methods to generate molecular ions are disclosed. At least a first species is ionized in an ion source. The first species ions and/or first species combine to form molecular ions. These molecular ions may be transported to a second chamber, which may be an arc chamber or diffusion chamber, and are extracted. The molecular ions may have a larger atomic mass than the first species or first species ions. A second species also may be ionized with the first species to form molecular ions. In one instance, the first and second species are both molecules. | 10-20-2011 |
20110300696 | METHOD FOR DAMAGE-FREE JUNCTION FORMATION - Embodiments of this doping method may be used to improve junction formation. An implant species, such as helium or another noble gas, is implanted into a workpiece to a first depth. A dopant is deposited on a surface of the workpiece. During an anneal, the dopant diffuses to the first depth. The noble gas ions may at least partially amorphize the workpiece during the implant. The workpiece may be planar or non-planar. The implant and deposition may occur in a system without breaking vacuum. | 12-08-2011 |
20120145918 | METHOD OF IONIZATION - A plasma is formed from one or more gases in a plasma chamber using at least a first power and a second power. A first ion species is generated at said first power and a second ion species is generated at said second power. In one embodiment, the first ion species and second ion species are implanted into a workpiece at two different energies using at least a first bias voltage and a second bias voltage. This may enable implantation to two different depths. These on species may be atomic ions or molecular ions. The molecular ions may be larger than the gases used to form the plasma. | 06-14-2012 |
20120258600 | METHOD AND SYSTEM FOR POST-ETCH TREATMENT OF PATTERNED SUBSTRATE FEATURES - A method of patterning a substrate, comprises providing a set of patterned features on the substrate, exposing the set of patterned features to a dose of ions incident on the substrate over multiple angles, and selectively etching exposed portions of the patterned features. | 10-11-2012 |
20140273502 | TECHNIQUES TO MITIGATE STRAGGLE DAMAGE TO SENSITIVE STRUCTURES - A method for processing a substrate includes providing a set of patterned structures separated by a first gap on the substrate and directing first implanting ions to the substrate at a first ion energy, where the first implanting ions are effective to impact the substrate in regions defined by the first gap. The method also includes directing depositing ions to the substrate where the second ions are effective to deposit material on at least a portion of the set of patterned structures to form expanded patterned structures, where the expanded patterned structures are characterized by a second gap smaller than the first gap. The method further includes directing second implanting ions to the substrate at a second ion energy, where the second implanting ions effective to impact the substrate in regions defined by the second gap, the second ion energy comprising a higher ion energy than the first ion energy. | 09-18-2014 |