A discharge detection apparatus includes a vacuum container, a conductive installation member in the vacuum container, the installation member being connected to the vacuum container so as to be retained by the vacuum container; a conductive antenna in the vacuum container; and a retainer comprising a material having a specific resistance of 1×10.sup.5 to 1×10.sup.11 (Ω.Math.cm), the retainer retaining the antenna with respect to the installation member without a contact between the installation member and the antenna, by means of a screw located through an inside of the antenna and an inside of the retainer.

A method for exposing a pattern in an area on a surface using a charged particle beam lithography is disclosed and includes inputting an original set of exposure information for the area. The area comprises a plurality of pixels, and the original set of exposure information comprises dosages for the plurality of pixels in the area. A backscatter is calculated for a sub area of the area based on the original set of exposure information. A dosage for at least one pixel in a plurality of pixels in the sub area is increased, in a location where the backscatter of the sub area is below a pre-determined threshold, thereby increasing the backscatter of the sub area. A modified set of exposure information is output, including the increased dosage of the at least one pixel in the sub area.

A method of operating a semiconductor apparatus includes forming a first electron beam passing through a first shaping aperture; modifying an energy distribution of the first electron beam by a second shaping aperture, such that the first electron beam has a main region and an edge region having a greater energy than the main region; and exposing a workpiece to the main region and the edge region of the first electron beam to create a pattern.

In one embodiment, a charged particle beam writing method includes transferring a substrate to a writing chamber of a charged particle beam writing apparatus by use of a transfer mechanism while maintaining each of the writing chamber and the transfer mechanism at a predetermined temperature, calculating correction amounts for charged particle beams based on correction data for charged particle beam irradiation positions each associated with a previously obtained elapsed time from a predetermined starting point in time of transfer of the substrate and the elapsed time at a point in time of irradiation with each of the charged particle beams, and applying the charged particle beams to positions corrected based on the calculated correction amounts for the charged particle beams to write a pattern on the substrate.

A method for exposing a pattern in an area on a surface using a charged particle beam lithography is disclosed and includes inputting an original set of exposure information for the area. The area comprises a plurality of pixels, and the original set of exposure information comprises dosages for the plurality of pixels in the area. A backscatter is calculated for a sub area of the area based on the original set of exposure information including the dosages for the plurality of pixels in the area. An increase in dosage for at least one pixel in a plurality of pixels in the sub area is determined, in a location where the backscatter of the sub area is below a pre-determined threshold, thereby increasing the backscatter of the sub area.

Nanopantography is a method for patterning nanofeatures over large areas. Transfer of patterns defined by nanopantography using highly selective plasma etching, with an oxide layer of silicon serving as a hard mask, can improve patterning speed and etch profile. With this method, high aspect ratio features can be fabricated in a substrate with no mask undercut. The ability to fabricate complex patterns using nanopantography, followed by highly selective plasma etching, provides improved patterning speed, feature aspect ratio, and etching profile.

A method includes generating an electron beam from a radiation source; modifying an energy distribution of the electron beam through a first shaping aperture; and exposing a substrate to portions of the electron beam passing through the first shaping aperture. The first shaping aperture comprises blocking strips with a plurality of slots therebetween, a frame surrounding the blocking strips, and a diagonal support connected to the frame and one of the blocking strips.

In one embodiment, a multi charged-particle beam writing apparatus includes a plurality of blankers switching between ON and OFF state of a corresponding beam among multiple beams, a main deflector deflecting beams having been subjected to blanking deflection to a writing position of the beams in accordance with movement of a stage, a detector scanning a mark on the stage with each of the beams having been deflected by the main deflector and detecting a beam position from a change in intensity of reflected charged particles and a position of the stage, and a beam shape calculator switching an ON beam, scanning the mark with the ON beam, and calculating a shape of the multiple beams from a beam position. A shape of a deflection field of the main deflector is corrected by using a polynomial representing an amount of beam position shift that is dependent on a beam deflection position of the main deflector and then the mark is scanned with the ON beam. The polynomial is different for each ON beam.

A charged particle beam writing apparatus includes an area density calculation unit to calculate a pattern area density weighted using a dose modulation value, which has previously been input from an outside and in which an amount of correction of a dimension variation due to a proximity effect has been included, a fogging correction dose coefficient calculation unit to calculate a fogging correction dose coefficient for correcting a dimension variation due to a fogging effect by using the pattern area density weighted using the dose modulation value having been input from the outside, a dose calculation unit to calculates a dose of a charged particle beam by using the fogging correction dose coefficient and the dose modulation value, and a writing unit to write a pattern on a target object with the charged particle beam of the dose.

In one embodiment, a charged particle beam drawing apparatus performs drawing by deflecting a charged particle beam with a deflector. A method for evaluating the apparatus includes making a shot of a first pattern, controlling a deflection amount by the deflector to move an applied position of the beam from the first pattern along a first direction to make a shot of a second pattern, controlling the deflection amount to move the applied position from the second pattern along the first direction to make a shot of a third pattern, controlling the deflection amount to move the applied position from the third pattern along a second direction opposite to the first direction to make a shot of a fourth pattern between the second pattern and the third pattern, calculating an interval between the second pattern and the fourth pattern, and comparing the calculated interval to a reference interval.