Lithographic apparatuses suitable for complementary e-beam lithography (CEBL) are described. In an example, a method of forming a pattern for a semiconductor structure includes forming a pattern of parallel lines above a substrate. The method also includes aligning the substrate in an e-beam tool to provide the pattern of parallel lines parallel with a scan direction of the e-beam tool. The e-beam tool includes a column having a blanker aperture array (BAA) with a staggered pair of columns of openings along an array direction orthogonal to the scan direction. The method also includes forming a pattern of cuts or vias in or above the pattern of parallel lines to provide line breaks for the pattern of parallel lines by scanning the substrate along the scan direction. A cumulative current through the column has a non-zero and substantially uniform cumulative current value throughout the scanning.

A system and method for controlling an amount of outgassing caused by implanting ions into a photoresist disposed on a workpiece. The amount of outgassing is based on the species being implanted, the type of photoresist, the energy of the implant, and the amount of dose that has already been implanted, among other effects. By controlling the effective beam current, the amount of outgassing may be maintained below a predetermined threshold. By developing and utilizing the relationship between effective beam current, dose completed and rate of outgassing, the effective beam current may be controlled more precisely to implant the workpiece in the most efficient manner while remaining below the predetermined outgassing threshold.

A method of scanning a substrate includes immobilizing a substrate on a substrate holder within a processing chamber and performing a pass of a parallel raster pattern by synchronously driving a first rotary drive and a second rotary drive to move the substrate relative to a processing apparatus focused on a localized spot on the substrate, the first rotary drive being coupled to a proximal end of a pendulum arm and the second rotary drive being mounted at a distal end of the pendulum arm and to the substrate holder. Driving the first rotary drive during the pass includes moving the pendulum arm in a first arc motion for a first portion of the pass while the localized spot is on the substrate, and then moving the pendulum arm in an opposite second arc motion for a second portion of the pass while the localized spot is on the substrate.

A method of processing a substrate includes loading the substrate on a substrate holder. The substrate includes a major surface and a feature disposed over the major surface. The feature has a first width along an etch direction. The method includes exposing portions of the major surface and changing the first width of the feature to a second width along the etch direction by etching a first portion of the sidewalls of the feature with a gas cluster ion beam oriented along a beam direction.

A scanning system includes a scanning chamber; a first rotary drive disposed in the scanning chamber and configured to rotate around a first axis; a second rotary drive disposed in the scanning chamber and configured to rotate around the first axis synchronously with the first rotary drive; and a bar-and-hinge system disposed in the scanning chamber and mechanically coupled to a substrate holder, the hinge system configured to translate a rotary motion of the first rotary drive and the second rotary drive to a planar motion of the substrate holder.

An ion source. The ion source may include a plasma chamber to house a plasma, and an extraction assembly, disposed along a side of the plasma chamber, and comprising at least one extraction aperture. The ion source may further include an antenna assembly, extending through the plasma chamber, along a first axis. The antenna assembly may include a dielectric enclosure, a plurality of conductive antennae, extending along the first axis within the dielectric enclosure.

A semiconductor manufacturing apparatus according to the present embodiment includes a stage on which a wafer can be placed. A separator separates a beam of impurities to be introduced into the wafer into an ion component and a neutral component. A controller switches the semiconductor manufacturing apparatus between a first mode and a second mode, where in the first mode, the ion component is introduced into the wafer and in the second mode, the neutral component is introduced into the wafer.

A film-forming apparatus comprises: a processing chamber defining a processing space, a first sputter-particle emitter and a second sputter-particle emitter having targets, respectively, from which sputter-particles are emitted in different oblique directions in the processing space, a sputter-particle blocking plate having a passage hole through which the sputter particles emitted from the first sputter-particle emitter and the second sputter-particle emitter pass, a substrate support configured to support a substrate and provided at a side opposite the first sputter-particle emitter and the second sputter-particle emitter with respect to the sputter-particle blocking plate in the processing space, a substrate moving mechanism configured to linearly move the substrate supported on the substrate support, and a controller configured to control the emission of sputter-particles from the first sputter-particle emitter and the second sputter-particle emitter while controlling the substrate moving mechanism to move the substrate linearly.

An electron beam apparatus is provided. The apparatus comprises an e-beam source configured to generate an electron beam, a first part configured to support a substrate, the first part comprising an object table for supporting the substrate, the first part further comprising a short stroke actuator system for actuating the object table relative to the e-beam source, the short stroke actuator system comprising a short stroke forcer. The apparatus further comprises a second part configured to movably support the first part and a long stroke actuator system configured to actuate movement of the first part with respect to the second part, the long stroke actuator system comprising a long stroke forcer, wherein the short stroke forcer and/or the long stroke forcer is configured to be switched off while the electron beam is projected onto the substrate.

The present disclosure provides a method to adjust asymmetric velocity of a scan in a scanning ion beam etch process to correct asymmetry of etching between the inboard side and the outboard side of device structures on a wafer, while maintaining the overall uniformity of etch across the full wafer.