Abstract: Provided is a charged particle beam applied apparatus for observing a sample, provided with: a beam-forming section that forms a plurality of charged particle beams on a sample; an energy control unit that controls the incident energy of the plurality of charged particle beams that are irradiated onto the sample; a beam current control unit that controls the beam current of the plurality of charged particle beams that are irradiated onto the sample; and a beam arrangement control unit that controls the arrangement in which the plurality of charged particle beams is irradiated onto the sample. The beam-forming section includes a beam splitting electrode, a lens array upper electrode, a lens array middle electrode, a lens array lower electrode and a movable stage, and functions as the beam current control unit or the beam arrangement control unit through selection, by the movable stage, of a plurality of aperture pattern sets.

Abstract: Provided is a charged particle beam applied apparatus for observing a sample, provided with: a beam-forming section that forms a plurality of charged particle beams on a sample; an energy control unit that controls the incident energy of the plurality of charged particle beams that are irradiated onto the sample; a beam current control unit that controls the beam current of the plurality of charged particle beams that are irradiated onto the sample; and a beam arrangement control unit that controls the arrangement in which the plurality of charged particle beams is irradiated onto the sample. The beam-forming section includes a beam splitting electrode, a lens array upper electrode, a lens array middle electrode, a lens array lower electrode and a movable stage, and functions as the beam current control unit or the beam arrangement control unit through selection, by the movable stage, of a plurality of aperture pattern sets.

Abstract: An electron beam apparatus equipped with a review function of a semiconductor wafer includes a scanning electron microscope to obtain image information of a semiconductor wafer, and an information processing apparatus to process the image information. The information processing apparatus includes a data input unit to receive positional information of a defect on the wafer, a storage for storing a plurality of image information of a position on the wafer corresponding to the positional information, and an image processing unit that retrieves any of the plurality of image information, and classifies the retrieved image information corresponding to the positional information depending on the type of defect.

Abstract: Disclosed is a charged particle beam device, wherein multibeam secondary electron detectors (121a, 121b, 121c) and a single beam detector (140; 640) are provided, and under the control of a system control unit (135), an optical system control circuit (139) controls a lens and a beam selecting diaphragm (141) and switches the electrooptical conditions between those for multibeam mode and those for single beam mode, thereby one charged particle beam device can be operated as a multibeam charged particle device and a single beam charged particle device by switching. Thus, observation conditions are flexibly changed in accordance with an object to be observed, and a sample can be observed with a high accuracy and high efficiency.

Abstract: Provided is a pattern inspection apparatus including: a charge formation means which forms charge on a surface of a substrate (7) by generating an electron beam from a second electron source (20) which is different from an electron source (1) which generates an electron beam before irradiating an electron beam (3), a current measuring means (34) which measures a value of current flowing in the substrate while the charge is formed on the surface of the substrate by the charge formation means; and an adjustment means (37) which adjusts the charge formed by the charge formation means so that the value of the current measured by the current measuring means is a predetermined target value. Provided is also a pattern inspection method which uses the pattern inspection apparatus. Thus, it is possible to easily set an optimal condition of precharge executed before inspection of a pattern formed by a semiconductor apparatus manufacturing process and automatically inspection whether the precharge is good.

Abstract: High-speed inspection is performed with appropriate sensitivity according to the pattern density and pattern characteristic of a device. The pixel dimension used in image acquisition is changed in accordance with the pattern density of a device. An image is acquired at high speed by changing the beam scan speed and the stage drive speed in accordance with the pixel dimension and eliminating an error by controlling the amount of beam delay. The acquired image is so resampled that the image dimensions of the acquired image and a reference image are equally sized, and the acquired image and the reference image are then aligned with each other. The aligned images are resampled in accordance with a preset pixel dimension to extract a difference between the images with the sensitivity according to the pixel dimension.

Abstract: Disclosed is a charged particle beam device, wherein multibeam secondary electron detectors (121a, 121b, 121c) and a single beam detector (140; 640) are provided, and under the control of a system control unit (135), an optical system control circuit (139) controls a lens and a beam selecting diaphragm (141) and switches the electrooptical conditions between those for multibeam mode and those for single beam mode, thereby one charged particle beam device can be operated as a multibeam charged particle device and a single beam charged particle device by switching. Thus, observation conditions are flexibly changed in accordance with an object to be observed, and a sample can be observed with a high accuracy and high efficiency.

Abstract: Provided is a pattern inspection apparatus including: a charge formation means which forms charge on a surface of a substrate (7) by generating an electron beam from a second electron source (20) which is different from an electron source (I) which generates an electron beam before irradiating an electron beam (3), a current measuring means (34) which measures a value of current flowing in the substrate while the charge is formed on the surface of the substrate by the charge formation means; and an adjustment means (37) which adjusts the charge formed by the charge formation means so that the value of the current measured by the current measuring means is a predetermined target value. Provided is also a pattern inspection method which uses the pattern inspection apparatus. Thus, it is possible to easily set an optimal condition of precharge executed before inspection of a pattern formed by a semiconductor apparatus manufacturing process and automatically inspection whether the precharge is good.

Abstract: An inspection apparatus and method are provided capable of suppressing electron beam focus drifts and irradiation-position deviations caused by sample surface charge-up by irradiation of an electron beam during micropattern inspection to thereby avoid false defect detection and also shorten an inspection time. The apparatus captures a plurality of images of alignment marks provided at dies, stores in a storage device deviations between the central coordinates of alignment mark images and the coordinates of the marks as a coordinate correction value, measures heights at a plurality of coordinates on the sample surface, captures images of the measured coordinates to perform focus adjustment, saves the relationship between such adjusted values and the sensor-measured heights in the storage as height correction values, and uses inspection conditions including the image coordinate correction values saved in the storage and the height correction values to correct the image coordinates and height of the sample.

Abstract: A circuit pattern inspection method and an apparatus therefore, in which the whole of a portion to be inspected of a sample to be inspected is made to be in a predetermined changed state, the portion to be inspected is irradiated with an image-forming high-density electron beam while scanning the electron beam, secondary charged particles are detected at a portion irradiated with the electron beam after a predetermined period of time from an instance when the electron beam is irradiated, an image is formed on the basis of the thus detected secondary charged particle signal, and the portion to be inspected is inspected by using the thus formed image.

Abstract: Electron beam is irradiated to a wafer in the midst of steps at predetermined intervals by a plurality of times under a condition in which a junction becomes rearward bias and a difference in characteristic of a time period of alleviating charge in the rearward bias is monitored. As a result, charge is alleviated at a location where junction leakage is caused in a time period shorter than that of a normal portion and therefore, a potential difference is produced between the normal portion and a failed portion and is observed in a potential contrast image as a difference in brightness. By consecutively repeating operation of acquiring the image, executing an image processing in real time and storing a position and brightness of the failed portion, the automatic inspection of a designated region can be executed. Information of image, brightness and distribution of the failed portion is preserved and outputted automatically after inspection.

Abstract: An electron beam system includes a sample holder to hold a sample, electron optics to obtain an image of the sample, an electrode to control a charged state of the sample, a monitor to determine a range of voltage applied to the electrode, and a processing unit to obtain plural images of different charged states of the sample in accordance with a change of the applied to the electrode and to determine voltage from the voltage contrasts of the images.

Abstract: Secondary electrons and back scattered electrons generated by irradiating a wafer to be inspected such as a semiconductor wafer with a charged particle beam are detected by a detector. A signal proportional to the number of detected electrons is generated, and an inspection image is formed on the basis of the signal. On the other hand, in consideration of a current value and irradiation energy of a charged particle beam, an electric field on the surface of the inspection wafer, emission efficiency of the secondary electrons and back scattered electrons, and the like, an electric resistance and an electric capacitance are determined so as to coincide with those in the inspection image. In a state where a difference between a resistance value in a normal portion and a resistance value in a defective portion is sufficiently increased by using the charging generated by the irradiation of electron beams, an inspection is conducted to thereby detect a defect.

Abstract: Secondary electrons and back scattered electrons generated by irradiating a wafer to be inspected such as a semiconductor wafer with a charged particle beam are detected by a detector. A signal proportional to the number of detected electrons is generated, and an inspection image is formed on the basis of the signal. On the other hand, in consideration of a current value and irradiation energy of a charged particle beam, an electric field on the surface of the inspection wafer, emission efficiency of the secondary electrons and back scattered electrons, and the like, an electric resistance and an electric capacitance are determined so as to coincide with those in the inspection image. In a state where a difference between a resistance value in a normal portion and a resistance value in a defective portion is sufficiently increased by using the charging generated by the irradiation of electron beams, an inspection is conducted to thereby detect a defect.

Abstract: An electron beam system using a scanning electron microscope equipped with a function for controlling a charged state of a sample to be observed includes electron optics for obtaining image data of the scanning electron microscope, and a monitor that displays a relationship between an equation for determining a degree of separation of peaks which appear in a histogram obtained on a basis of the image data and at least one parameter among parameters for controlling the charged state of the sample. An optimized parameter for controlling the charged stage of the sample can be visually distinguished on the monitor.

Abstract: A circuit pattern inspection method and an apparatus therefor, in which the whole of a portion to be inspected of a sample to be inspected is made to be in a predetermined changed state, the portion to be inspected is irradiated with an image-forming high-density electron beam while scanning the electron beam, secondary charged particles are detected at a portion irradiated with the electron beam after a predetermined period of time from an instance when the electron beam is irradiated, an image is formed on the basis of the thus detected secondary charged particle signal, and the portion to be inspected is inspected by using the thus formed image.

Abstract: A circuit pattern inspection method and an apparatus therefor, in which the whole of a portion to be inspected of a sample to be inspected is made to be in a predetermined charged state, the portion to be inspected is irradiated with an image-forming high-density electron beam while scanning the electron beam, secondary charged particles are detected at a portion irradiated with the electron beam after a predetermined period of time from an instance when the electron beam is irradiated, an image is formed on the basis of the thus detected secondary charged particle signal, and the portion to be inspected is inspected by using the thus formed image.

Abstract: An apparatus for inspecting a sample using a scanning electron microscope includes a sample stage, a first electron-optical system to scan an electron beam of a first beam current on the sample, a second electron-optical system to scan an electron beam of a second beam current smaller than the first beam current on the sample, a mechanism to move the sample stage, a detector provided in each of the first and second electron-optical systems to detect a secondary electron. The first electron-optical system is operable in a first mode and the second electron-optical system is operable in a second mode with higher resolution than that of the first mode. In the first mode, the sample is observed while the sample stage is moved continuously, and in the second mode, the sample is observed by detecting a secondary electron using the detector while the sample stage is held stationary.

Abstract: When the electrode potential of a charge control electrode above a wafer is reduced, image brightness is reduced. A point of change in the image brightness is a switching point between a positively charged state of the image and a negatively charged state of the image, showing the weakly charged state of the image. By setting this point of change as an inspecting condition, the amount of electric charges on the surface of the wafer can be reduced, and stable wafer inspection can be performed. It is estimated that an applied voltage V1 in FIG. 14 corresponds to the point of the change and is roughly included in the voltage range of a region enclosed by a broken line in the vicinity of the applied voltage V1. Within this voltage range, the influence of charge on an inspection under the inspecting condition can be reduced.

Abstract: Electron beam is irradiated to a wafer in the midst of steps at predetermined intervals by a plurality of times under a condition in which a junction becomes rearward bias and a difference in characteristic of a time period of alleviating charge in the rearward bias is monitored. As a result, charge is alleviated at a location where junction leakage is caused in a time period shorter than that of a normal portion and therefore, a potential difference is produced between the normal portion and a failed portion and is observed in a potential contrast image as a difference in brightness. By consecutively repeating operation of acquiring the image, executing an image processing in real time and storing a position and brightness of the failed portion, the automatic inspection of a designated region can be executed. Information of image, brightness and distribution of the failed portion is preserved and outputted automatically after inspection.