According to one aspect of the present invention, an electron beam apparatus includes charge amount distribution operation processing circuitry that operates a charge amount distribution of an irradiation region in a case that a substrate is irradiated with an electron beam using a combined function combining a first exponential function having an inflection point and at least one of a first-order proportional function and a second exponential function that converges and depending on a pattern area density; positional displacement operation processing circuitry that operates a positional displacement of an irradiation pattern formed due to irradiation of the electron beam using the charge amount distribution obtained; correction processing circuitry that corrects an irradiation position using the positional displacement; and an electron beam column including an emission source that emits the electron beam and a deflector that deflects the electron beam to irradiate a corrected irradiation position with the electron beam.

A semiconductor device and method is disclosed. In one example, the method for forming a semiconductor device includes forming a trench extending from a front side surface of a semiconductor substrate into the semiconductor substrate. The method includes forming of material to be structured inside the trench. Material to be structured is irradiated with a tilted reactive ion beam at a non-orthogonal angle with respect to the front side surface such that an undesired portion of the material to be structured is removed due to the irradiation with the tilted reactive ion beam while an irradiation of another portion of the material to be structured is masked by an edge of the trench.

The invention relates to a collimator electrode stack (70), comprising: at least three collimator electrodes (71-80) for collimating a charged particle beam along an optical axis (A), wherein each collimator electrode comprises an electrode body with an electrode aperture for allowing passage to the charged particle beam, wherein the electrode bodies are spaced along an axial direction (Z) which is substantially parallel with the optical axis, and wherein the electrode apertures are coaxially aligned along the optical axis; and a plurality of spacing structures (89) provided between each pair of adjacent collimator electrodes and made of an electrically insulating material, for positioning the collimator electrodes at predetermined distances along the axial direction. Each of the collimator electrodes (71-80) is electrically connected to a separate voltage output (151-160). The invention further relates to a method of operating a charged particle beam generator.

A method of manufacturing a substrate is disclosed. The method includes receiving a plurality of pixel elements, wherein each of the pixel elements includes data members; and transferring the data members to a plurality of exposing devices that are configured to conditionally expose the substrate with an incident energy beam when coupled with the data members, wherein different data members of one pixel element are transferred at different system cycles.

In one embodiment, a multi charged particle beam writing apparatus includes an emitter that emits a charged particle beam, an aperture plate in which a plurality of openings are formed and that forms multiple beams by allowing the charged particle beam to pass through the plurality of openings, a blanking plate provided with a plurality of blankers that each perform blanking deflection on a corresponding beam included in the multiple beams, a stage on which a substrate irradiated with the multiple beams, a detector that detects a reflection charged particle from the substrate, feature amount calculation circuitry that calculates a feature amount of an aperture image based on a detection value of the detector, and aberration correction circuitry that corrects aberration of the charged particle beam based on the feature amount.

A multi charged particle beam exposing method includes setting, in multiple exposures by a plurality of shots of each beam of multi-beams where the plurality of shots continuously irradiate a same irradiation position, a plurality of clock periods including at least one different clock period where the plurality of clock periods individually control an irradiation time of each beam of the multi-beams such that a clock period of at least one exposure processing differs from clock periods of other exposure processing, and exposing respective corresponding irradiation positions on a target object with the multi-beams by controlling, in each exposure processing of the multiple exposures, the irradiation time in exposure processing concerned using a clock period which has been set in the plurality of clock periods including the at least one different clock period.

An ion implanter includes a high energy multi-stage linear acceleration unit including a plurality of linear acceleration units, wherein each of the linear acceleration units includes high frequency accelerators respectively in a plurality of stages; and a control device controlling an operation of the high energy multi-stage linear acceleration unit in accordance with a data set defining a voltage amplitude, a frequency, and a phase of the high frequency accelerator in each of the plurality of stages.

Methods, devices and systems for targeted, maskless modification of material on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform direct and knock-on ion implantation, producing patterned material modifications with selected chemical and 3D-structural profiles. The number of required process steps is reduced, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding individual columns, and support superior, highly-configurable process execution and control. Targeted implantation can be used to prepare the substrate for patterned blanket etch; patterned ALD can be used to prepare the substrate for patterned blanket deposition; neither process requiring photomasks or resist. Arrays of highly configurable beam columns can also be used to perform both positive and negative tone lithography in a single pass.

Methods, devices and systems for targeted, maskless modification of material on or in a substrate using charged particle beams. Electrostatically-deflected charged particle beam columns can be targeted in direct dependence on the design layout database to perform direct and knock-on ion implantation, producing patterned material modifications with selected chemical and 3D-structural profiles. The number of required process steps is reduced, reducing manufacturing cycle time and increasing yield by lowering the probability of defect introduction. Local gas and photon injectors and detectors are local to corresponding individual columns, and support superior, highly-configurable process execution and control. Targeted implantation can be used to prepare the substrate for patterned blanket etch; patterned ALD can be used to prepare the substrate for patterned blanket deposition; neither process requiring photomasks or resist. Arrays of highly configurable beam columns can also be used to perform both positive and negative tone lithography in a single pass.

A device for detecting X-rays radiated out of a substrate surface, said device comprising at least one X-ray detector, a resolver grating and a modulator grating, said resolver grating with at least one opening facing towards said X-ray detector is arranged in front of said X-ray detector. Said modulator grating is provided between said resolver grating and said substrate at a predetermined distance from said resolver grating and said substrate, where said modulator grating having a plurality of openings in at least a first direction, wherein said x-rays from said surface is spatially modulated with said modulator grating and resolver grating.