Abstract: Disclosed is a standard specimen, used with an electron microscope to correct the magnification with high precision. A standard member used for correction corrects a scanning electron microscope that measures a pattern within an observation region based on information about the secondary electrons generated by scanning incident electron lines on the observation region on a measurement specimen, or information about the reflected electron intensity. The standard member has a first pattern region that corrects the magnification and that comprises a concavo-convex pattern (line/space pattern) in the cross section of a multilayer film that has been laminated, and a second pattern region near the first pattern at almost the same height that does not contain a pattern with the same periodicity as the pattern pitch size of the first region and that is used for beam adjustment.

Abstract: A scanning electron microscope suppresses a beam drift by reducing charging on a sample surface while suppressing resolution degradation upon observation of an insulator sample. An electron microscope includes an electron source and an objective lens that focuses an electron beam emitted from the electron source, which provides an image using a secondary signal generated from the sample irradiated with the electron beam. A magnetic body with a continuous structure and an inside diameter larger than an inside diameter of an upper pole piece that forms the objective lens is provided between the objective lens and the sample.

Abstract: Provided is a scanning electron microscope including: an image recording unit (112) which stores a plurality of acquired frame images; a correction analyzing handling unit (113) which calculates a drift amount between frame images and a drift amount between a plurality of field images constituting a frame image; and a data handling unit (111) which corrects positions of respective field images constituting the plurality of fields images according to the drift amount between the field images and superimposes the field images on one another so as to create a new frame image. This provides a scanning electron microscope which can obtain a clear frame image even if an image drift is caused during observation of a pattern on a semiconductor substrate or an insulating object.

Abstract: The present invention provides a reticle inspection technology that enables a relative position between patterns to be evaluated for a pattern that may become a defect at the time of exposure to a sample, such as a wafer, in the double patterning technology on the same layer.

Abstract: In order to provide a charged beam device capable of obtaining a precise image of a sample surface pattern while improving the accuracy of automatic focus/astigmatism correction, there are provided an electron gun (1), a deflection control portion (8) which allows an electron beam to scan, a focus control portion (10) and an astigmatism correction portion (3) for the electron beam, an image processing portion (11), and a switching portion (9) which switches scan conditions when obtaining pattern information of the sample (1001) surface and scan conditions when performing the automatic focus/astigmatism correction, and a scan speed and scan procedures are switched between when obtaining the pattern information and when performing the automatic focus/astigmatism correction.

Abstract: Provided is a scanning electron microscope including: an image recording unit (112) which stores a plurality of acquired frame images; a correction analyzing handling unit (113) which calculates a drift amount between frame images and a drift amount between a plurality of field images constituting a frame image; and a data handling unit (111) which corrects positions of respective field images constituting the plurality of fields images according to the drift amount between the field images and superimposes the field images on one another so as to create a new frame image. This provides a scanning electron microscope which can obtain a clear frame image even if an image drift is caused during observation of a pattern on a semiconductor substrate or an insulating object.

Abstract: The astigmatism control processing time is decreased to 1 second or less by improving the astigmatic difference measurement accuracy. A charged particle beam device includes: a stage on which a sample is loaded; a transport mechanism which carries the sample onto the stage; a charged particle beam optical system which irradiates the sample on the stage with a charged particle beam and detects secondary charged particles generated from the sample; and a controller which determines setup parameters for the charged particle beam optical system and controls the charged particle beam optical system. The controller registers and holds electro-optical system setup parameters for irradiation with a beam tilted from a normal line on the sample as the charged particle beam, compares observation images obtained by the tilted beam, measures the amount and direction of movement and calculates the amount of astigmatism correction from the amount of movement and the direction.

Abstract: Disclosed is a standard specimen, used with an electron microscope to correct the magnification with high precision. A standard member used for correction corrects a scanning electron microscope that measures a pattern within an observation region based on information about the secondary electrons generated by scanning incident electron lines on the observation region on a measurement specimen, or information about the reflected electron intensity. The standard member has a first pattern region that corrects the magnification and that comprises a concavo-convex pattern (line/space pattern) in the cross section of a multilayer film that has been laminated, and a second pattern region near the first pattern at almost the same height that does not contain a pattern with the same periodicity as the pattern pitch size of the first region and that is used for beam adjustment.

Abstract: A method for enabling management of fatal defects of semiconductor integrated patterns easily, the method enables storing of design data of each pattern designed by a semiconductor integrated circuit designer, as well as storing of design intent data having pattern importance levels ranked according to their design intents respectively. The method also enables anticipating of defects to be generated systematically due to the characteristics of the subject exposure system, etc. while each designed circuit pattern is exposed and delineated onto a wafer in a simulation carried out beforehand and storing those defects as hot spot information. Furthermore, the method also enables combining of the design intent data with hot spot information to limit inspection spots that might include systematic defects at high possibility with respect to the characteristics of the object semiconductor integrated circuit and shorten the defect inspection time significantly.

Abstract: The present invention provides an electron beam measurement technique for measuring the shapes or sizes of portions of patterns on a sample, or detecting a defect or the like. An electron beam measurement apparatus has a unit for irradiating the patterns delineated on a substrate by a multi-exposure method, and classifying the patterns in an acquired image into multiple groups according to an exposure history record. The exposure history record is obtained based on brightness of the patterns and a difference between white bands of the patterns.

Abstract: The present invention provides an electron beam measurement technique for measuring the shapes or sizes of portions of patterns on a sample, or detecting a defect or the like. An electron beam measurement apparatus has a unit for irradiating the patterns delineated on a substrate by a multi-exposure method, and classifying the patterns in an acquired image into multiple groups according to an exposure history record. The exposure history record is obtained based on brightness of the patterns and a difference between white bands of the patterns.

Abstract: The invention provides a standard component for calibration that enables a calibration position to be easily specified in order to calibrate accurately a scale factor in the electron-beam system, and provides an electron-beam system using it. The standard component for calibration is one that calibrates a scale factor of an electron-beam system based on a signal of secondary charged particles detected by irradiation of a primary electron beam on a substrate having a cross section of a superlattice of a multi-layer structure in which different materials are deposited alternately. The substrate has linear patterns on the substrate surface parallel to the multi-layers and are arranged at a fixed interval in a direction crossing the cross section of the superlattice pattern, and the cross sections of the linear patterns are on substantially the same plane of the superlattice cross section, so that the linear patterns enable a position of the superlattice pattern to be identified.

Abstract: In method and apparatus for obtaining a scanning electron microscope image devoid of distortion by measuring a scanning distortion and calibrating the scanning distortion, there occurs a problem that an error takes place in dimension control owing to a scanning distortion of an electron beam. To cope with this problem, an image is obtained by scanning a predetermined region with the electron beam, a plurality of regions are selected from the image, the pattern pitch is measured in each of the regions and a scanning distortion amount is calculated from the result of measurement and then corrected.

Abstract: Method of forming a pattern by a nanoimprint technique starts with preparing a mold with nanostructures on its surface. The mold is pressed against a substrate or plate coated with a resin film. The positions of alignment marks formed on the rear surface of the plate coated with the resin film are detected. Thus, a relative alignment between the mold and the plate coated with the resin film is performed.

Abstract: Correction of widths obtained by measurement of a sample with the use of a scanning electron microscope is executed with greater precision. A standard sample for correction comprises a plurality of correction mark members, the respective correction mark members, being lined up at specified intervals in a specified direction, and respective widths thereof, in the specified direction, differing from each other so as to be of respective sizes as pre-set. Measurement of the respective widths of the correction mark members is made to obtain respective measurement widths while authorized widths of the correction mark members are kept stored in an image processing unit of the scanning electron microscope to thereby find differences between the respective measurement widths, and authorized widths corresponding thereto, and the differences are stored as respective correction functions to correct the measurement width of the sample.

Abstract: The present invention provides a pattern inspection technique that enables measurement and inspection of a fine pattern by a charged particle beam to be performed with high throughput.

Abstract: It is to provide a technology that can quickly process many measurement points on a substrate by a primary charged particle beam. In a control system, with respect to each measurement point (irradiation position of the primary charged particle beam) on a wafer, a calculator obtains a probability of a surface potential at a relevant measurement point that is obtained from a surface potential distribution function of the wafer and is stored in a data storage unit. Based on the probability, the calculator determines an amplitude of a set parameter (for example, retarding voltage) of charged particle optics at the relevant measurement point. Then the calculator checks the focus state of the primary charged particle beam by changing the set parameter in the range of the determined amplitude, and determines the set parameter to be used for measurement.

Abstract: The present invention provides a standard reference component for calibration for performing magnification calibration used in the scanning electron microscope with high precision, and provides a scanning electron microscope technique using it.

Abstract: A method for enabling management of fatal defects of semiconductor integrated patterns easily, the method enables storing of design data of each pattern designed by a semiconductor integrated circuit designer, as well as storing of design intent data having pattern importance levels ranked according to their design intents respectively. The method also enables anticipating of defects to be generated systematically due to the characteristics of the subject exposure system, etc. while each designed circuit pattern is exposed and delineated onto a wafer in a simulation carried out beforehand and storing those defects as hot spot information. Furthermore, the method also enables combining of the design intent data with hot spot information to limit inspection spots that might include systematic defects at high possibility with respect to the characteristics of the object semiconductor integrated circuit and shorten the defect inspection time significantly.

Abstract: The present invention provides an electron beam measurement technique for measuring the shapes or sizes of portions of patterns on a sample, or detecting a defect or the like. An electron beam measurement apparatus has a unit for irradiating the patterns delineated on a substrate by a multi-exposure method, and classifying the patterns in an acquired image into multiple groups according to an exposure history record. The exposure history record is obtained based on brightness of the patterns and a difference between white bands of the patterns.