Lithographic apparatuses suitable for, and methodologies involving, complementary e-beam lithography (CEBL) are described. In an example, a column for an e-beam direct write lithography tool includes a first blanker aperture array (BAA) including a staggered array of openings having a pitch along an array direction. The array direction is orthogonal to a scan direction. Each opening has a first dimension in the array direction. The column also includes a second BAA including a staggered array of openings having the pitch along the array direction. Each opening has a second dimension in the array direction, the second dimension greater than the first dimension.

Disclosed herein an apparatus and a method for detecting buried features using backscattered particles. In an example, the apparatus comprises a source of charged particles; a stage; optics configured to direct a beam of the charged particles to a sample supported on the stage; a signal detector configured to detect backscattered particles of the charged particles in the beam from the sample; wherein the signal detector has angular resolution. In an example, the methods comprises obtaining an image of backscattered particles from a region of a sample; determining existence or location of a buried feature based on the image.

In one embodiment, a data processing method is provided for generating writing data from design data and registering the writing data in a charged particle beam writing apparatus. The method includes generating the writing data by performing a plurality of conversion processes on a plurality of pieces of first frame data obtained through division of the design data corresponding to one chip, and performing a plurality of preprocessing processes on a plurality of pieces of second frame data obtained through division of the writing data of the chip, and registering the writing data of the chip in the charged particle beam writing apparatus. The plurality of conversion processes are performed in frame-basis pipeline processing, and the plurality of preprocessing processes are performed in frame-basis pipeline processing. The writing data is registered in the charged particle beam writing apparatus on a frame basis.

A drawing data generating method according to an embodiment is a method for generating drawing data input to a drawing apparatus that draws a plurality of figure patterns on an object using a charged particle beam. The method includes generating the drawing data in accordance with a data format that not only defines a plurality of pieces of figure information, but also sequentially defines dose information of each figure before or after the plurality of pieces of figure information. The dose information of each of the second and succeeding figures is converted to a representation based on the dose information of any preceding figure, and a data length of the dose information is made variable for each figure. For example, the dose information of each of the second and succeeding figures is converted to a difference representation between a dose of the figure and a dose of the preceding figure, and a data length of the difference representation is changed in accordance with the magnitude of a difference value.

A charged particle beam lithography apparatus, includes a plurality of multiple-beam sets, each of which including a plurality of irradiation sources each generating an independent charged particle beam, a plurality of objective deflectors, each arranged for a corresponding charged particle beam, and configured to deflect the corresponding charged particle beam to a desired position on a substrate, and a plurality of electrostatic or electromagnetic lens fields each to focus the corresponding charged particle beam on the target object; a plurality of common deflection amplifiers, arranged for each multiple-beam set, and each of the plurality of common deflection amplifiers being configured to commonly control the plurality of objective deflectors arranged in a same multiple-beam set; a plurality of individual ON/OFF mechanisms configured to individually turn ON/OFF a beam irradiated from each irradiation source; and one or more multiple-beam clusters including the plurality of multiple-beam sets.

A multi-charged particle beam writing apparatus according to one aspect of the present invention includes a region setting unit configured to set, as an irradiation region for a beam array to be used, the region of the central portion of an irradiation region for all of multiple beams of charged particle beams implemented to be emittable by a multiple beam irradiation mechanism, and a writing mechanism, including the multiple beam irradiation mechanism, configured to write a pattern on a target object with the beam array in the region of the central portion having been set in the multiple beams implemented.

In one embodiment, a first storage storing writing data, a second storage storing correction data for correcting an error in a writing position due to factors including bending of the substrate, a cell data allocator virtually dividing a writing region of the substrate into blocks, and allocating a cell to the blocks in consideration of the correction data, a plurality of bitmap data generators virtually dividing the blocks into meshes, calculating an irradiation amount per mesh region, and generating bitmap data which assigns the irradiation amount to each mesh region, and a shot data generator generating shot data that defines an irradiation time for each beam. The cell data allocator virtually divides the writing region by division lines in a direction different from a writing forward direction to generate a plurality of division regions. The plurality of bitmap data generators generate pieces of bitmap data of the different division regions.

A charged particle beam writing apparatus includes a division/distribution processing unit to divide and distribute processed data into data groups each having an approximately equal data amount respectively, transmitting units to transmit the processed data of the groups such that processed data is transmitted in descending order with respect to order of writing processing for each data group and the groups are transmitted in parallel, memories to store the processed data of the groups such that each of the memories stores processed data of each different one of the groups, a writing order data output unit to output them, regardless of data group and in order of writing processing, and a writing unit to write a pattern on a target workpiece with a charged particle beam, based on the processed data output in the order of writing processing.

Lithographic apparatuses suitable for, and methodologies involving, complementary e-beam lithography (CEBL) are described. In an example, a blanker aperture array (BAA) for an e-beam tool includes a first column of openings along a first direction. The BAA also includes a second column of openings along the first direction and staggered from the first column of openings. The first and second columns of openings together form an array having a pitch in the first direction. A scan direction of the BAA is along a second direction, orthogonal to the first direction. The pitch of the array corresponds to half of a minimal pitch layout of a target pattern of lines for orientation parallel with the second direction.

In one embodiment, a writing data generation method is for generating writing data used by a multi-charged particle beam writing apparatus. The writing data generation method includes referring to library data in which a vertex sequence including a plurality of vertices is registered, and extracting a portion of an outer line of a figure contained in design data, the portion corresponding to the vertex sequence, and representing the extracted portion by information which identifies the vertex sequence and information which indicates a connection method for the plurality of vertices of the vertex sequence, and generating the writing data.