An ion implantation system and method that selectively varies an ion beam energy to a workpiece in sequential passes thereof in front of the beam. The implantation system has an ion source for generating the ion beam and an acceleration/deceleration stage for varying the energy of the ion beam based on an electrical bias supplied to the acceleration deceleration stage. A workpiece support is provided immediately downstream of the acceleration/deceleration stage to support a workpiece through the selectively varied energy ion beam, and can be thermally controlled to control a temperature of the workpiece during the variation of energy of the beam. The energy can be varied while the workpiece is positioned in front of the beam, and a controller can control the electrical bias to control the variation in energy of the ion beam, where a plurality of process recipes can be attained during a single positioning of the workpiece on the workpiece support.

An ion source for an ion implantation system is configured to form an ion beam from a predetermined species along a beamline, where the ion beam is at an initial energy. A deceleration component is configured to decelerate the ion beam to a final energy that is less than the initial energy. A workpiece support is configured to support a workpiece along a workpiece plane downstream of the deceleration component along the beamline. A beamline component is positioned downstream of the deceleration component along the beamline. The beamline component has a feature that is at least partially impinged by the ion beam, and where the feature has a surface having a predetermined angle of incidence with respect to the ion beam. The predetermined angle of incidence provides a predetermined sputter yield of the ion beam at the final energy that mitigates deposition of the ion species on the beamline component.

A method comprising the irradiation of a wafer by an ion beam that passes through an implantation filter. The wafer is heated to a temperature of more than 200° C. The wafer is a semiconductor wafer including SiC, and the ion beam includes aluminum ions.

The present disclosure relates to an ion beam etching (IBE) system including a process chamber. The process chamber includes a plasma chamber configured to provide plasma. In addition, the process chamber includes an accelerator grid having multiple accelerator grid elements including a first accelerator grid element and a second accelerator grid element. A first wire is coupled to the first accelerator grid element and configured to supply a first voltage to the first accelerator grid element. A second wire is coupled to the second accelerator grid element and configured to supply a second voltage to the second accelerator grid element, where the second voltage is different from the first voltage. A first ion beam through a first hole is controlled by the first accelerator grid element, and a second ion beam through a second hole is controlled by the second accelerator grid element.

In one embodiment, an electron beam inspection apparatus includes an optical system irradiating a substrate with primary electron beams, a beam separator separating, from the primary electron beams, secondary electron beams emitted as a result of irradiating the substrate with the primary electron beams, a detector detecting the secondary electron beams separated, a movable stage on which the substrate is placed, a support base supporting the substrate on the stage, and an applying unit applying a first voltage to the substrate. The support base includes a plurality of support pins that support the substrate from below. The support pins each include a columnar insulator and a metal film disposed in the insulator. A second voltage is applied to the metal film.

An ion implantation device (20) comprising an energy filter (25), wherein the energy filter (25) has a thermal energy dissipation surface area, wherein the energy filter (25) comprises a membrane with a first surface and a second surface disposed opposite to the first surface, the first surface being a structured surface.

An ion implantation device (20) is provided comprising an energy filter (25) with a structured membrane, wherein the energy filter (25) is heated by absorbed energy from the ion beam, and at least one additional heating element (50a-d, 55a-d, 60, 70) for heating the energy filter (25).

Substrate processing systems, such as ion implantation systems, deposition systems and etch systems, having textured silicon liners are disclosed. The silicon liners are textured using a chemical treatment that produces small features, referred to as micropyramids, which may be less than 20 micrometers in height. Despite the fact that these micropyramids are much smaller than the textured features commonly found in graphite liners, the textured silicon is able to hold deposited coatings and resist flaking. Methods for performing preventative maintenance on these substrate processing systems are also disclosed.

To provide a scanning electron microscope having an electron spectroscopy system to attain high spatial resolution and a high secondary electron detection rate under the condition that energy of primary electrons is low, the scanning electron microscope includes: an objective lens 105; primary electron acceleration means 104 that accelerates primary electrons 102; primary electron deceleration means 109 that decelerates the primary electrons and irradiates them to a sample 106; a secondary electron deflector 103 that deflects secondary electrons 110 from the sample to the outside of an optical axis of the primary electrons; a spectroscope 111 that disperses secondary electrons; and a controller that controls application voltage to the objective lens, the primary electron acceleration means and the primary electron deceleration means so as to converge the secondary electrons to an entrance of the spectroscope.

A device for implanting particles in a substrate comprises a particle source and a particle accelerator for generating an ion beam of positively charged ions. The device also comprises a substrate holder and an energy filter, which is arranged between the particle accelerator and the substrate holder. The energy filter is a microstructured membrane with a predefined structural profile for setting a dopant depth profile and/or a defect depth profile produced in the substrate by the implantation. The device also comprises at least one passive braking element for the ion beam. The at least one passive braking element is arranged between the particle accelerator and the substrate holder and is spaced apart from the energy filter.