A system for transporting substrates and precisely alignment the substrates to shadow masks. The system decouples the functions of transporting the substrates, vertically aligning the substrates, and horizontally aligning the substrates. The transport system includes a carriage upon which plurality of pedestals are loosely positioned, each of the pedestals includes a base having vertical alignment wheels to place the substrate in precise vertical alignment. Two sidebars are configured to freely slide on the base. Each of the sidebars includes a set of horizontal alignment wheels that precisely align the substrate in the horizontal direction. Substrate support claws are attached to the sidebars in precise alignment to the vertical alignment wheels and the horizontal alignment wheels.

A semiconductor wafer includes a first surface and an implantation area adjacent to the first surface and a certain distance away from the first surface, the implantation area including implanted particles and defects. A defect concentration in the implantation area deviates by less than 5% from a maximum defect concentration in the implantation area.

A method of monitoring compliance with filter specification during the implantation of ions into a substrate reading a signature of the filter and comparing the read signature with filter signatures stored in a database to identify properties of the filter including at least one of a maximum allowable temperature of the filter and a maximum allowable accumulated ion dose of the filter. The temperature and/or the accumulated ion dose of the filter is measured while ions are implanted into the substrate by an ion beam passing through the filter. The implantation is terminated when the measured temperature or accumulated ion dose of the filter reaches or exceeds the maximum allowable threshold.

A method of fabricating non-uniform gratings includes implanting different densities of ions into corresponding areas of a substrate, patterning, e.g., by lithography, a resist layer on the substrate, etching the substrate with the patterned resist layer, and then removing the resist layer from the substrate, leaving the substrate with at least one grating having non-uniform characteristics associated with the different densities of ions implanted in the areas. The method can further include using the substrate having the grating as a mold to fabricate a corresponding grating having corresponding non-uniform characteristics, e.g., by nanoimprint lithography.

There is provided a semiconductor device manufacturing method including: forming a first mask film composed of a polymer having a urea bond by supplying a raw material to a surface of the substrate for polymerization; forming a second mask inorganic film to be laminated on the first mask film; forming a pattern on the first mask film and the second mask inorganic film and performing an ion implantation on the surface of the substrate; removing the second mask inorganic film after the ion implantation; and removing the first mask film by heating the substrate after the ion implantation and depolymerizing the polymer.

A method of fabricating non-uniform gratings includes implanting different densities of ions into corresponding areas of a substrate, patterning, e.g., by lithography, a resist layer on the substrate, etching the substrate with the patterned resist layer, and then removing the resist layer from the substrate, leaving the substrate with at least one grating having non-uniform characteristics associated with the different densities of ions implanted in the areas. The method can further include using the substrate having the grating as a mold to fabricate a corresponding grating having corresponding non-uniform characteristics, e.g., by nanoimprint lithography.

A method of producing an implantation ion energy filter, suitable for processing a power semiconductor device. In one example, the method includes creating a preform having a first structure; providing an energy filter body material; and structuring the energy filter body material by using the preform, thereby establishing an energy filter body having a second structure.

A method comprising the irradiation of a wafer by an ion beam that passes through an implantation filter, the ion beam being electrostatically deviated in a first direction and a second direction in order to move the ion beam over the wafer, and the implantation filter being moved in the second direction to match the movement of the ion beam.

A method of producing an implantation ion energy filter, suitable for processing a power semiconductor device. In one example, the method includes creating a preform having a first structure; providing an energy filter body material; and structuring the energy filter body material by using the preform, thereby establishing an energy filter body having a second structure.

An implantation device, an implantation system and a method. The implantation device comprises a filter frame and a filter held by the filter frame, wherein said filter is designed to be irradiated by an ion beam.