Method of manufacturing electronic devices using a maskless lithographic exposure system using a maskless pattern writer. The method comprises generating beamlet control data for controlling the maskless pattern writer to expose a wafer for creation of the electronic devices, wherein the beamlet control data is generated based on a feature data set defining features selectable for individualizing the electronic devices, wherein exposure of the wafer according to the beamlet control data results in exposing a pattern having a different selection of the features from the feature data set for different subsets of the electronic devices.

An electron beam writing apparatus according to the present invention includes a potential regulating member arranged to be upstream of a target object in the case where the target object is placed on a stage, and configured to be set to have a fixed potential being positive with respect to the target object, a potential applying circuit configured to apply a voltage to the target object or the potential regulating member so that the potential regulating member has the fixed potential, and a correction circuit configured to correct a positional deviation of the electron beam on a surface of the target object which occurs in the case where the target object is irradiated with the electron beam in the state in which the potential regulating member has the fixed potential.

An electron beam lithography (Ebeam) method for a wafer having alignment and device layers with a design alignment. The Ebeam method includes executing an Ebeam scan of predefined length and resolution based on the design alignment over a pattern edge of the device layer, generating a signal from reflections of the Ebeam scan off the pattern edge, determining an offset of the device layer relative to the alignment layer from a comparison of the signal and the design alignment and applying the offset to the design alignment to obtain an actual measurement of Ebeam alignment.

A method for mask data synthesis and mask making includes calibrating an optical proximity correction (OPC) model by adjusting a plurality of parameters including a first parameter and a second parameter, wherein the first parameter indicates a long-range effect caused by an electron-beam lithography tool for making a mask used to manufacture a structure, and the second parameter indicates a geometric feature of a structure or a manufacturing process to make the structure, generating a device layout, calculating a first grid pattern density map of the device layout, generating a long-range correction map, at least based on the calibrated OPC model and the first grid pattern density map of the device layout, and performing an OPC to generate a corrected mask layout, at least based on the generated long-range correction map and the calibrated OPC model.

An electron beam lithography system and an electron beam lithography process are disclosed herein for improving throughput. An exemplary method for increasing throughput achieved by an electron beam lithography system includes receiving an integrated circuit (IC) design layout that includes a target pattern, wherein the electron beam lithography system implements a first exposure dose to form the target pattern on a workpiece based on the IC design layout. The method further includes inserting a dummy pattern into the IC design layout to increase a pattern density of the IC design layout to greater than or equal to a threshold pattern density, thereby generating a modified IC design layout. The electron beam lithography system implements a second exposure dose that is less than the first exposure dose to form the target pattern on the workpiece based on the modified IC design layout.

A parameter acquiring method for dose correction of a charged particle beam includes writing evaluation patterns on a substrate coated with resist; writing, while varying writing condition, a peripheral pattern on a periphery of any different one of the evaluation patterns, after an ignorable time as to influence of resist temperature increase due to writing of an evaluation pattern concerned has passed; and calculating a parameter for defining correlation among a width dimension change amount of the evaluation pattern concerned, a temperature increase amount of the evaluation pattern concerned, and a backscatter dose reaching the evaluation pattern concerned, by using, under each writing condition, a width dimension of the evaluation pattern concerned, the temperature increase amount of the evaluation pattern concerned at each shot time, and the backscatter dose reaching the evaluation pattern concerned from each shot.

A method for projecting a particle beam onto a substrate, the method includes a step of calculating a correction of the scattering effects of the beam by means of a point spread function modelling the forward scattering effects of the particles; a step of modifying a dose profile of the beam, implementing the correction thus calculated; and a step of projecting the beam, the dose profile of which has been modified, onto the substrate, and being wherein the point spread function is, or comprises by way of expression of a linear combination, a two-dimensional double sigmoid function. A method to e-beam lithography is also provided.

An electron beam lithography apparatus-includes: a density set storage unit that stores, for each of pieces of figure information, a set of pieces of first density information corresponding to areas occupied by a figure in first small regions divided from a figure region specified by the piece of figure information; a density set acquisition unit that acquires first density sets respectively corresponding to the pieces of figure information from the density set storage unit; a correction amount acquisition unit that acquires correction amounts corresponding to the first density sets for each of the pieces of figure information, and are for the second small regions; an emission amount acquisition unit that acquires, for the second small regions, emission amounts of an electron beam with intensities corresponding to the correction amounts for the second small regions; and a drawing unit that emits an electron beam according to the emission amounts.

Method of manufacturing electronic devices using a maskless lithographic exposure system using a maskless pattern writer. The method comprises generating beamlet control data for controlling the maskless pattern writer to expose a wafer for creation of the electronic devices, wherein the beamlet control data is generated based on a feature data set defining features selectable for individualizing the electronic devices, wherein exposure of the wafer according to the beamlet control data results in exposing a pattern having a different selection of the features from the feature data set for different subsets of the electronic devices.

A method for mask data synthesis and mask making includes calibrating an optical proximity correction (OPC) model by adjusting a plurality of parameters including a first parameter and a second parameter, wherein the first parameter indicates a long-range effect caused by an electron-beam lithography tool for making a mask used to manufacture a structure, and the second parameter indicates a geometric feature of a structure or a manufacturing process to make the structure, generating a device layout, calculating a first grid pattern density map of the device layout, generating a long-range correction map, at least based on the calibrated OPC model and the first grid pattern density map of the device layout, and performing an OPC to generate a corrected mask layout, at least based on the generated long-range correction map and the calibrated OPC model.