Provided herein are deposition systems utilizing coated grids in an ion deposition process which provide more predictable erosion of the coating rather than erosion of the grid itself. Further, coatings may be utilized in which the coating material does not act as a contaminant to the deposition process, thereby eliminating contamination of the sample surface due to deposition of unwanted grid material. Also provided are methods of refurbishing a coated grid by periodically replacing the coating material thus protecting the grid itself and allowing a grid to be used indefinitely.

A method of depositing material over a sample in a deposition region of the sample with a charged particle beam column, the method comprising: positioning a sample within a vacuum chamber such that the deposition region is under a field of view of the charged particle beam column; cooling the deposition region by contacting the sample with a cyro-nanomanipulator tool in an area adjacent to the deposition region; injecting a deposition precursor gas into the vacuum chamber at a location adjacent to the deposition region; generating a charged particle beam with a charged particle beam column and focusing the charged particle beam on the sample; and scanning the focused electron beam across the localized region of the sample to activate molecules of the deposition gas that have adhered to the sample surface in the deposition region and deposit material on the sample within the deposition region

An ion beam deposition apparatus includes a substrate assembly to secure a substrate, a target assembly slanted with respect to the substrate assembly, the target assembly including a target with deposition materials, an ion gun to inject ion beams onto the target, such that ions of the deposition materials are discharged toward the substrate assembly to form a thin layer on the substrate, and a substrate heater to heat the substrate to a deposition temperature higher than a room temperature.

A system includes an ion source configured to generate ions having a first polarity, one or more extraction electrodes configured to extract the ions from the ion source as an ion beam having an extraction energy, a mass resolving slit or aperture configured to select a desired isotope from the ion beam such that a desired isotopic ion beam passes through the mass resolving slit or aperture, a target positioned relative to the mass resolving slit or aperture so that the desired isotopic ion beam is incident on the target, and a voltage source coupled to the target and configured to hold the target at a first voltage having the first polarity. The first voltage causes a reduction of the extraction energy as the desired isotopic ion beam approaches the target to minimize sputtering and maximize collection of the ions on the target to reconstitute an ionized material.

The present disclosure relates to systems and methods of additive manufacturing that reduce or eliminates defects in the bulk deposition material microstructure resulting from the additive manufacturing process. An additive manufacturing system comprises evaporating a deposition material to form an evaporated deposition material and ionizing the evaporated deposition material to form an ionized deposition material flux. After forming the ionized deposition material flux, the ionized deposition material flux is directed through an aperture, accelerated to a controlled kinetic energy level and deposited onto a surface of a substrate. The aperture mechanism may comprise a physical, electrical, or magnetic aperture mechanism. Evaporation of the deposition material may be performed with an evaporation mechanism comprised of resistive heating, inductive heating, thermal radiation, electron heating, and electrical arc source heating.

An optical device as described herein includes a host substrate fabricated from a dielectric material transparent in the Infrared range. Additionally, the optical device as discussed herein includes multiple elements disposed on the host substrate. The multiple elements are spaced apart from each other on the host substrate in accordance with a desired pattern. Each of the multiple elements disposed in the host substrate is fabricated from a second material having a refractive index of greater than 4.5. Such an optical device provides an improvement over conventional optical devices that operate in the Infrared range.

A manufacturing method of a semiconductor device includes the steps of: (a) placing a semiconductor wafer over a stage provided in a chamber, the pressure in the inside of which is reduced by vacuum pumping; and (b) after the step (a), forming plasma in the chamber in a state where the semiconductor wafer is adsorbed and held by the stage, so that desired etching processing is performed on the semiconductor wafer. Herein, before the step (a), O.sub.2 gas, negative gas having an electronegativity higher than that of nitrogen gas, is introduced into the chamber to form O.sub.2 plasma in the chamber, thereby allowing the charges remaining over the stage to be eliminated.

Method for the particle beam-induced etching of a lithography mask, more particularly a non-transmissive EUV lithography mask, having the steps of: a) providing the lithography mask in a process atmosphere, b) beaming a focused particle beam onto a target position on the lithography mask, c) supplying at least one first gaseous component to the target position in the process atmosphere, where the first gaseous component can be converted by activation into a reactive form, where the reactive form reacts with a material of the lithography mask to form a volatile compound, and d) supplying at least one second gaseous component to the target position in the process atmosphere, where the second gaseous component under predetermined process conditions with exposure to the particle beam forms a deposit comprising a compound of silicon with oxygen, nitrogen and/or carbon.

Provided are a laminated body and a laminated body manufacturing method that can improve adhesiveness between a resin layer and a seed layer. The laminated body has a substrate, a first wiring layer, a resin layer, and a second wiring layer in this order, and the second wiring layer includes at least an adhesive layer and a seed layer in this order.

A mask pattern is formed on a substrate. A first spacer film is formed on the mask pattern. The first spacer film is etched by irradiating the substrate with a gas cluster ion beam (GCIB). A first spacer pattern is formed on the substrate by removing the mask pattern. A second spacer film is formed on the first spacer pattern. The second spacer film is etched. A second spacer pattern is formed on the substrate by removing the first spacer pattern. The substrate is etched using the second spacer pattern as a mask.