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 radiated, 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: 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 this 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 thereby conducted to detect a defect.

Abstract: An electron beam (area beam) having a fixed area is irradiated onto the surface of a semiconductor sample, and reflected electrons from the sample surface are imaged by the imaging lens, and images of a plurality of regions of the surface of the semiconductor sample are obtained and stored in the image storage unit, and the stored images of the plurality of regions are compared with each other, and the existence of a defect in the regions and the defect position are measured. By doing this, in an apparatus for testing a pattern defect of the same design, foreign substances, and residuals on a wafer in the manufacturing process of a semiconductor apparatus by an electron beam, speeding-up of the test can be realized.

Abstract: In the detecting system for irradiating the electron beam and detecting the secondary electron thereof, an area of the detector is an important factor for high-speed detection. For the technique of the current electron optical system and detector, a detector of the area larger than a constant area is necessary and detection of 200 Msps or more by receiving limitation on the frequency inversely proportional to the area is substantially difficult. For example, for detection at 400 Msps under the condition that the required area is 4 mm square and the rate for 4 mm square is defined as 150 Msps, four discrete high-speed detectors of 2 mm square are arranged to amplify and then add the signals for A/D conversion. Otherwise, the secondary electron is sequentially inputted to the detector of 8 mm square with the secondary electron deflector, the secondary electron is detected at 100 Msps and arranged after the A/D conversion. In any case, the area of 4 mm square and rate of 400 Msps can be attained.

Abstract: A workpiece holder for holding a workpiece, which is used for an electron beam application apparatus for processing a workpiece by irradiating the surface of said workpiece with an electron beam, or observing the surface state of a workpiece by detecting secondary electrons produced from the workpiece by irradiation of the workpiece with an electron beam, includes a positioning portion which comes closer to an end portion of said workpiece when said workpiece holder holds the workpiece, thereby positioning the workpiece, in which the surface height of the end portion of the workpiece is nearly equal to the height of said positioning portion.

Abstract: Heights of a sample are calibrated by setting a calibrating substrate on a stage and then irradiating a charged particle beam onto standard marks provided on at least two kinds of surfaces having different substrate heights. Secondary charged particles produced from said irradiated standard marks on the substrate are and detected and a surface height of the irradiated portion of the substrate measured. The difference in height between the standard marks is set to be in a range containing an extent, over the entire sample, to which the height of the sample varies due to warping.

Abstract: An electric field for decelerating an electron beam is formed on a surface of a sample semiconductor to be inspected, an electron beam having a specific area (a sheet electron beam) and containing a component having such an energy as not to reach the surface of the sample semiconductor is reflected in the very vicinity of the surface of the sample semiconductor by action of the electric field for deceleration and then forms an image through an imaging lens. Thus images of plural fields on the surface of the sample semiconductor are obtained and are stored in image memory units. By comparing the stored images of the plural fields with one another, the presence and position of a defect in the fields are determined.

Abstract: In order to obtain optimum irradiation conditions of an electron beam according to the material and structure of a circuit pattern to be inspected and the kind of a failure to be detected and inspect under the optimum conditions without delay of the inspection time, an inspection device for irradiating the electron beam 19 to the sample board 9 which is a sample, detecting generated secondary electrons by the detector 7, storing obtained signals sequentially in the storage, comparing the same pattern stored in the storage by the comparison calculation unit, and extracting a failure by comparing the predetermined threshold value with the comparison signal by the failure decision unit is provided, wherein the optimum value of the irradiation energy is stored in the data base inside the device beforehand according to the structure of a sample and a recommended value of the irradiation energy suited to inspection can be searched for by inputting or selecting the irradiation energy by a user or inputting informati

Abstract: A circuit pattern inspecting instrument includes an electron-optical system for irradiating an electron beam on a sample, an electron beam deflector, a detector for detecting secondary charged particles from the sample, and a mode setting unit for switching between a first mode and a second mode. An electron beam current is larger in the first mode than in the second mode, and an electron beam scanning speed is higher in the first mode than in the second mode. The circuit pattern inspecting instrument is configured so that first the sample is observed in the first mode, then a particular position on the sample is selected based on image data produced by an output of the detector in the first mode, and then the particular position on the sample is observed in the second mode.

Abstract: A semiconductor fabricating apparatus for fabricating a semiconductor wafer includes a processing chamber, in which a workpiece is processed by irradiating the surface of said workpiece with an electron beam, a workpiece holder including a positioning portion for positioning the workpiece. The surface height of an end portion of the workpiece is nearly equal to the height of the positioning portion when the workpiece carried in the processing chamber is held on the workpiece holder.

Abstract: A convergent charged particle beam apparatus and method includes an electron beam image observation arrangement which observes an electron beam image of a surface of a specimen mounted on a movable stage inside of a vacuum chamber when an electron beam converged by an electron optical system is irradiated and scanned over the surface of the specimen and detecting secondary charged particles produced from the specimen so as to provide electron image data of the surface. A height detector optically detects a surface height of the specimen by irradiating light from outside of the vacuum chamber onto the specimen and detecting reflected light from the specimen with a detector disposed outside of the vacuum chamber. A controller controls a focal point of the converged and focused electron beam in accordance with the output from the height detector, and a display displays the electron image of the surface of the specimen.

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 object of the present invention is to provide an inspection method using an electron beam and an inspection apparatus therefor, which are capable of enhancing the resolution, improving the inspection speed and reliability, and realizing miniaturization the apparatus.

Abstract: The present invention is intended to highly fast, stably acquire highly accurate images from irradiated positions with an electron beam on a circuit pattern in the step of fabricating a semiconductor device including an insulating material or a mixture of an insulating material and a conductive material, without occurrence of any deviation in the irradiated position in the images to be comparatively inspected, automatically comparing the images with each other thereby inspecting defects of the circuit pattern without occurrence of errors, and feeding back the result to the conditions of fabricating the semiconductor device thereby increasing the reliability of the semiconductor device and reducing the defective percentage thereof.

Abstract: In a pattern inspection device of the present invention having at least three electron-optical systems, detection signals approximately simultaneously obtained from identical circuit patterns are compared with each other. Further, areas around plural electron sources can be maintained at high degrees of vacuum by evacuating an electron gun chamber mounted with plural electron guns independently of a sample chamber. Further, electric fields and magnetic fields are confined in each electron-optical system by a shield electrode which makes it possible to evacuate an electron beam path to a high degree of vacuum, and at the same time, secondary electrons and reflected electrons are detected in the same electron-optical system by setting the samples to a negative voltage and accelerating secondary electrons and reflected electrons toward the electron source side in the direction of the electron beam axis.

Abstract: Problems encountered in the conventional inspection method and the conventional apparatus adopting the method are solved by the present invention using an electron beam by providing a novel inspection method and an inspection apparatus adopting the novel method which are capable of increasing the speed to scan a specimen such as a semiconductor wafer. The inspection novel method provided by the present invention comprises the steps of: generating an electron beam; converging the generated electron beam on a specimen by using an objective lens; scanning the specimen by using the converged electron beam; continuously moving the specimen during scanning; detecting charged particles emanating from the specimen at a location between the specimen and the objective lens and converting the detected charged particles into an electrical signal; storing picture information conveyed by the electrical signal; comparing a picture with another by using the stored picture information; and detecting a defect of the specimen.

Abstract: An electron beam (area beam) having a fixed area is irradiated onto the surface of a semiconductor sample, and reflected electrons from the sample surface are imaged by the imaging lens, and images of a plurality of regions of the surface of the semiconductor sample are obtained and stored in the image storage unit, and the stored images of the plurality of regions are compared with each other, and the existence of a defect in the regions and the defect position are measured. By doing this, in an apparatus for testing a pattern defect of the same design, foreign substances, and residuals on a wafer in the manufacturing process of a semiconductor apparatus by an electron beam, speeding-up of the test can be realized.

Abstract: In a high-sensitivity X-ray detector, an image of the secondary electrons is little shifted and deformed by the astigmatism or the like even when it approaches very close to a specimen set on the stage of an electron microscope. When a beam of charged particles strike a specimen, the specimen emits backscattered charged particles along with X-rays. To prevent such undesired charged particles from entering into the X-ray detecting element of the X-ray detector, a means for generating a first magnetic field is applied. Another means for generating a second magnetic field is provided to cancel the magnetic filed leaked from the first means for generating magnetic field at the position of the specimen.

Abstract: An inspection method and apparatus includes control of an acceleration voltage of an electron beam, irradiation of the electron beam to an object to be inspected mounted on a stage which is continuously moving at least in one direction, and detection of at least one of secondary electrons and reflected electrons emanated from the object in response to the irradiation. An image of the object is obtained from the detected electron by using positional information of the stage and inspection or measurement of the object is conducted using an obtained image. In the detection, an electric field in the vicinity of the object mounted on the stage is controlled so that at least one of the secondary electrons and the reflected electrons emanated from the object in response to the irradiation of the electron beam are decelerated.

Abstract: Problems encountered in the conventional inspection method and the conventional apparatus adopting the method are solved by the present invention using an electron beam by providing a novel inspection method and an inspection apparatus adopting the novel method which are capable of increasing the speed to scan a specimen such as a semiconductor wafer.