Abstract: A charge transfer mechanism is used to locally deposit or remove material for a small structure. A local electrochemical cell is created without having to immerse the entire work piece in a bath. The charge transfer mechanism can be used together with a charged particle beam or laser system to modify small structures, such as integrated circuits or micro-electromechanical system. The charge transfer process can be performed in air or, in some embodiments, in a vacuum chamber.

Abstract: A cathode having electron production and focusing grooves for an ion source of an ion implanter system, the ion source and a related method are disclosed. In one embodiment, the cathode includes a working surface having a plurality of electron production and focusing grooves positioned therein. A repeller of the ion source may be similarly structured.

Abstract: An ion source that utilizes exited and/or atomic gas injection is disclosed. In an ion beam application, the source gas can be used directly, as it is traditionally supplied. Alternatively or additionally, the source gas can be altered by passing it through a remote plasma source prior to being introduced to the ion source chamber. This can be used to create excited neutrals, heavy ions, metastable molecules or multiply charged ions. In another embodiment, multiple gasses are used, where one or more of the gasses are passed through a remote plasma generator. In certain embodiments, the gasses are combined in a single plasma generator before being supplied to the ion source chamber. In plasma immersion applications, plasma is injected into the process chamber through one or more additional gas injection locations. These injection locations allow the influx of additional plasma, produced by remote plasma sources external to the process chamber.

Abstract: A cathode having electron production and focusing grooves for an ion source of an ion implanter system, the ion source and a related method are disclosed. In one embodiment, the cathode includes a working surface having a plurality of electron production and focusing grooves positioned therein. A repeller of the ion source may be similarly structured.

Abstract: A charge transfer mechanism is used to locally deposit or remove material for a small structure. A local electrochemical cell is created without having to immerse the entire work piece in a bath. The charge transfer mechanism can be used together with a charged particle beam or laser system to modify small structures, such as integrated circuits or micro-electromechanical system. The charge transfer process can be performed in air or, in some embodiments, in a vacuum chamber.

Abstract: Liner elements to protect the ion source housing and also increase the power efficiency of the ion source are disclosed. Two liner elements, preferably constructed from tungsten, are inserted into the ion source chamber, one placed against each of the two sidewalls. These inserts are electrically biased so as to induce an electrical field that is perpendicular to the applied magnetic field. Such an arrangement has been unexpectedly found to increase the life of not only the ion chamber housing, but also the indirectly heated cathode (IHC) and the repeller. In addition, the use of these biased liner elements also improved the power efficiency of the ion source; allowing more ions to be generated at a given power level, or an equal number of ions to be generated at a lower power level.

Abstract: A cathode having electron production and focusing grooves for an ion source of an ion implanter system, the ion source and a related method are disclosed. In one embodiment, the cathode includes a working surface having a plurality of electron production and focusing grooves positioned therein. A repeller of the ion source may be similarly structured.

Abstract: A method of improving focused ion beam milling particularly suitable for uniformly removing multiple layers of conductor and dielectric, such as the removal of multiple layers consisting of dummy copper pads and SiO2 on a semiconductor device. Variable Pixel Milling is first used to more uniformly remove most of a layer of conductor and dielectric. The use of Variable Pixel Milling may also be used in conjunction with a technique whereby incoming ions pass through a sacrificial layer formed on the surface of the layer being removed in order to further increase uniformity of material removal. Focused ion beam sputtering in conjunction with an oxygen containing gas, such as H2O vapor or oxygen, is then used to smooth out the trench floor before the next layer is removed.

Abstract: The present invention provides a method for creating microscopic high resistivity structures on a target by directing a focused ion beam toward an impact point on the target and directing a precursor gas toward the impact point, the ion beam causing the precursor gas to decompose and thereby deposit a structure exhibiting high resistivity onto the target. The precursor gas preferably contains a first compound that would form a conductive layer and a second compound that would form an insulating layer if each of the first and second compounds were applied alone in the presence of the ion beam.

Abstract: A method of improving focused ion beam milling particularly suitable for uniformly removing multiple layers of conductor and dielectric, such as the removal of multiple layers consisting of dummy copper pads and SiO2 on a semiconductor device. Variable Pixel Milling is first used to more uniformly remove most of a layer of conductor and dielectric. The use of Variable Pixel Milling may also be used in conjunction with a technique whereby incoming ions pass through a sacrificial layer formed on the surface of the layer being removed in order to further increase uniformity of material removal. Focused ion beam sputtering in conjunction with an oxygen containing gas, such as H2O vapor or oxygen, is then used to smooth out the trench floor before the next layer is removed.

Abstract: The present invention provides a method for creating microscopic high resistivity structures on a target by directing a focused ion beam toward an impact point on the target and directing a precursor gas toward the impact point, the ion beam causing the precursor gas to decompose and thereby deposit a structure exhibiting high resistivity onto the target. The precursor gas preferably comprises a first compound that would form a conductive layer and a second compound that would form an insulating layer if each of the first and second compounds were applied alone in the presence of the ion beam.