Abstract: An inspection method and an inspection apparatus using an electron beam enabling more detailed and quantitative evaluation at a high throughput level. The method comprises the steps of irradiating, based on previously prepared information concerning a defect position on the surface of a sample, the defect and its vicinity with an electron beam a plurality of times at predetermined intervals; detecting an electron signal secondarily generated from the sample surface by the electron beam; imaging an electron signal detected by the previously specified n-th or later electron beam irradiation; and measuring the resistance or a leakage amount of the defective portion of the sample surface in accordance with the degree of charge relaxation by monitoring the charge relaxation state of the sample surface based on the electron beam image information.

Abstract: An inspection technique for enabling an inspection on a wafer at an early stage during a wafer process. A wafer in a process is irradiated with an electron beam a plurality of times at predetermined intervals under a condition that a junction is backward biased, and secondary electron signals are monitored, so as to evaluate relax time characteristic of a backward bias potential in a p-n junction. Since the potential in the p-n junction decreases according to the intensity of a backward bias current in intermittent time, a backward bias current can be specified from an intensity signal interrelated with the number of secondary electron signals, that is, a potential contrast image on the basis of image information.

Abstract: A semiconductor defect inspection device and method for detecting defects of partially finished substrates (semiconductor wafers) for semiconductor devices is provided. The substrate surface is irradiated with a charged particle beam and a voltage contrast image is obtained while the charged voltage is controlled at a desired level, and the electric resistances of the irradiated area from the image are calculated to detect a defect and identify the type of defect. Further, the distribution of electric resistances on the whole surface of the substrate can be quickly worked out. The charged particle beam irradiation conditions are varied in order to bring the charged voltage of the area to a desired value. With this device/method, electric resistances of small portions at desired charged voltages and the corresponding electric resistances are measured in a non-contact manner to determine the type of defect.

Abstract: A sample inspection system having a sample stage holding a sample to be inspected corresponding to a selected file, electron beam optics so as to radiate an electron beam to the sample, a detector unit that detects a secondly generated signal attributable to the electron beam, a storage for storing a plurality of images obtained from the secondly generated signal and information for classifying the plurality of images by a type of defect in the sample, and an image processing unit. The image processing unit retrieves any of the plurality of images and classifies the retrieved image depending on the type of defect including an electrical defect and a defect in the figure.

Abstract: By use of charged particle beam images picked up in different conditions, a positional displacement caused by parallax is analyzed, and an optics of an apparatus for charged particle beam microscopy is corrected automatically. An analysis method using phase difference of Fourier transform images and having analytic accuracy lower than that for one pixel is adopted for the displacement analysis. In addition, a degree of coincidence between images calculated in this analysis method is used as a criterion for evaluating the reliability of an analysis result. Since the analysis method based on parallax is low in specimen dependency, the operation range is expanded. In addition, by adopting a high-accuracy displacement analysis method, the apparatus correction accuracy is improved by one digit. A malfunction preventing flow is added using the degree of coincidence as a judgement criterion. Thus, the apparatus can deal with unmanned operation.

Abstract: A method of detecting a defect includes of determining an image acquisition condition for irradiating a converged electron beam onto a specimen and detecting a secondary electron emanated from the specimen, acquiring an image by detecting the secondary electron emanated from the specimen in synchronism with the irradiation of the electron beam, processing the acquired image to detect a defect on the specimen, and outputting information regarding the detected defect. The image acquisition condition is determined based on plural images which are acquired by changing at least one of acceleration condition of the secondary electron and an electrical field in the vicinity 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: 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: A method of detecting a defect includes of determining an image acquisition condition for irradiating a converged electron beam onto a specimen and detecting a secondary electron emanated from the specimen, acquiring an image by detecting the secondary electron emanated from the specimen in synchronism with the irradiation of the electron beam, processing the acquired image to detect a defect on the specimen, and outputting information regarding the detected defect. The image acquisition condition is determined based on plural images which are acquired by changing at least one of acceleration condition of the secondary electron and an electrical field in the vicinity of the specimen.

Abstract: A pattern inspection system for inspecting a substrate surface on which a predetermined pattern is formed with radiation of an electron beam and an optical beam. the pattern inspection system includes a radiation and which radiates an electron beam to the substrate, a detection unit which detects a secondarily generated signal attributable to the radiation of the electron beam, a retrieval unit which retrieves an image from the signal detected by the detection unit, and an image processing unit which classifies the retrieved image depending on a type of the image.

Abstract: Inspection method, apparatus, and system for a circuit pattern, in which when various conditions which are necessary in case of inspecting a fine circuit pattern by using an image formed by irradiating white light, a laser beam, or a charged particle beam are set, its operating efficiency can be improved. An inspection target region of an inspection-subject substrate is displayed, and a designated map picture plane and an image of an optical microscope or an electron beam microscope of a designated region are displayed in parallel, thereby enabling a defect distribution and a defect image to be simultaneously seen. Item names of inspecting conditions and a picture plane to display, input, or instruct the contents of the inspecting conditions are integrated, those contents are overlapped to the picture plane and layer-displayed, and all of the item names are displayed in parallel in a tab format in the upper portion of the picture plane of the contents.

Abstract: A process management system in accordance with the present invention includes inspection apparatuses for inspecting defects on a wafer, the inspection apparatuses being connected through a communication network, inspection information and image information obtained from these inspection apparatuses being collected to construct a data base and an image file, therein definition of defects is given by combinations of elements which characterize the defect based on the inspection information and the image information obtained from the inspection apparatuses. By giving definition of the defect, characteristics of the defect can be subdivided and known. Therefore, the cause of a defect can be studied.

Abstract: In a method for inspecting positions and types of defects on wafers with circuit patterns in a semiconductor manufacturing process, inspection is made regardless of the types and materials of junctions of circuit patterns of the semiconductor devices, different kinds of defects being distinguished from one another. Further, electrification of the circuit pattern is prevented, and the area to be exposed to an electron beam is controlled evenly and at a desired voltage. During inspection of the positions and types of defects on a wafer using a charged-particle beam from a charged-particle source, an optical beam from an optical source as well as a charged-particle beam are applied to a junction of the circuit pattern of the wafer placed on a wafer holder. Thus, regardless of the types and materials of circuit patterns, a highly sensitive inspection is made according to contrasts in the defects of a captured image.

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: 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: The present invention provides a wafer inspection technique capable of detecting a defect in a wafer on which a pattern having a large step such as a contact hole being subjected to a semiconductor manufacturing process is formed and obtaining information such as the position and kind of a defect such as a hole with open contact failure caused in dry etching process at high speed. A wafer on which a pattern having a large step being subjected to a semiconductor manufacturing process is formed is scanned and irradiated with an electron beam having irradiation energy which is in a range from 100 eV to 1,000 eV, and a defect is detected at high speed from an image of secondary electrons generated. Before the secondary electron image is captured, the wafer is irradiated with an electron beam at high speed while being moved to thereby charge the surface of the wafer with a desired charging voltage.

Abstract: An inspection method and an inspection apparatus using an electron beam enabling more detailed and quantitative evaluation at a high throughput level. The method comprises the steps of irradiating, based on previously prepared information concerning a defect position on the surface of a sample, the defect and its vicinity with an electron beam a plurality of times at predetermined intervals; detecting an electron signal secondarily generated from the sample surface by the electron beam; imaging an electron signal detected by the previously specified n-th or later electron beam irradiation; and measuring the resistance or a leakage amount of the defective portion of the sample surface in accordance with the degree of charge relaxation by monitoring the charge relaxation state of the sample surface based on the electron beam image information.

Abstract: Patterns on the surface of a workpiece are inspected by calculating characteristic quantities of the patterns, classifying detected defects automatically in clusters; calculating an occurrence distribution function for each cluster, and estimating the clusters automatically from the condition of a mass of defects that occurred in a characteristic space, if the defect occurrence distribution is unknown. Some of the defects in each of the clusters are reinspected after the classifying.

Abstract: A pattern inspection system for inspecting a substrate surface on which a predetermined pattern is formed with radiation of an electron beam and an optical beam. the pattern inspection system includes a radiation and which radiates an electron beam to the substrate, a detection unit which detects a secondarily generated signal attributable to the radiation of the electron beam, a retrieval unit which retrieves an image from the signal detected by the detection unit, and an image processing unit which classifies the retrieved image depending on a type of the image.

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