Abstract: In an accelerating tube which uses a conductive insulator, there is a possibility that the dopant concentration on a surface of the conductive insulator becomes non-uniform so that the surface resistance of the conductive insulator becomes non-uniform. Accordingly, a circumferential groove is formed on the inner surface of the conductive insulator accelerating tube in plural stages, and metal is metalized along inner portions of the grooves. When the resistance of a specific portion on the surface of the accelerating tube differs from the resistance of an area around the specific portion, the potential of the metalized region on the inner surface of the accelerating tube becomes a fixed value and hence, the potential distribution on the inner surface of the accelerating tube in the vertical direction can be maintained substantially equal without regard to the circumferential direction.

Abstract: The present invention provides a charged particle gun including: a charged particle source (1); an extraction electrode (2); an opening (14) through which a charged particle beam passes; and a barrier provided in an area defined by connecting the charged particle source to the opening, the barrier serving to prevent molecules existing in a downstream vacuum chamber from passing through the opening to adsorb onto the charged particle source. Accordingly, the molecules existing in the downstream lower-vacuum chamber can be prevented from adsorbing onto the charged particle source, so that current noise can be reduced. This enables stable operations of the charged particle beam gun and a charged particle beam device including the charged particle beam gun.

Abstract: A scanning electron microscope having a charged particle beam that when in a state being irradiated toward a sample, a voltage is applied to the sample so that the charged particle beam does not reach the sample. The scanning electron microscope also detects information on a potential of a sample using a signal obtained, and a device for automatically adjusting conditions based on the result of measuring.

Abstract: A scanning electron microscope having a charged particle beam that when in a state being irradiated toward a sample, a voltage is applied to the sample so that the charged particle beam does not reach the sample. The scanning electron microscope also detects information on a potential of a sample using a signal obtained, and a device for automatically adjusting conditions based on the result of measuring.

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: Because a mirror electron imaging type inspection apparatus for obtaining an inspection object image with mirror electrons has been difficult to optimize inspection conditions, since the image forming principles of the apparatus are different from those of conventional SEM type inspection apparatuses. In order to solve the above conventional problem, the present invention has made it possible for the user to examine such conditions as inspection speed, inspection sensitivity, etc. intuitively by displaying the relationship among the values of inspection speed S, inspection object digital signal image pixel size D, inspection object image size L, and image signal acquisition cycle P with use of a time delay integration method as a graph on an operation screen. The user can thus determine a set of values of a pixel size, an inspection image width, and a TDI sensor operation cycle easily with reference to the displayed graph.

Abstract: Because a mirror electron imaging type inspection apparatus for obtaining an inspection object image with mirror electrons has been difficult to optimize inspection conditions, since the image forming principles of the apparatus are different from those of conventional SEM type inspection apparatuses. In order to solve the above conventional problem, the present invention has made it possible for the user to examine such conditions as inspection speed, inspection sensitivity, etc. intuitively by displaying the relationship among the values of inspection speed S, inspection object digital signal image pixel size D, inspection object image size L, and image signal acquisition cycle P with use of a time delay integration method as a graph on an operation screen. The user can thus determine a set of values of a pixel size, an inspection image width, and a TDI sensor operation cycle easily with reference to the displayed graph.

Abstract: In the present invention, the structure of an electrification control electrode is changed from a grid type to a slit type and thereby shadows are not formed when a wafer is irradiated with a beam. Further, a beam forming slit is disposed ahead of an electrification control slit, thus the electrification control slit is prevented from being irradiated with an electron beam for preliminary electrification, and thereby secondary electrons which disturb the control of the electrification are inhibited from being generated. The shape of the slit is designed so that the strength of an electron beam may gradually decrease toward both the ends of an electron beam irradiation region in the longitudinal direction thereof. Furthermore, a preliminary static eliminator to remove or reduce the unevenness in an electrification potential distribution which has undesirably been formed earlier is disposed.

Abstract: Disclosed herein are a method for applying, while a charged particle beam is in a state being irradiated toward the sample, a voltage to the sample so that the charged particle beam does not reach the sample (hereafter such state may be referred to as a mirror state) and detecting information on a potential of a sample using a signal obtained then, and a device for automatically adjusting conditions of the device based on the result of measuring.

Abstract: An electron microscope includes an electron source, a stage for mounting a specimen, an illuminating lens system that illuminates an electron beam onto the specimen, an imaging lens system that forms a specimen image using a reflecting electron beam of the illuminating electron beam, a beam separator that separates the illuminating electron beam and the reflecting electron beam, a control unit that controls current to be supplied to the beam separator; and a switching unit which enables switching between a first mode and a second mode. The control unit changes a value of the current to be supplied to the beam separator when switching from the first mode to the second mode.

Abstract: An inspection apparatus comprising an electron emitting unit for sequentially emitting an electron beam in the direction of an inspection area of a sample; a deceleration unit for drawing back the electron beam in the vicinity of the inspection area; an imaging unit for forming images of the drawing back electron beam on multiple different image forming conditions; an image detecting unit for capturing the electron beam that formed an image corresponding to each image forming condition; and an image processing unit for comparing the images on different image forming conditions with one another to detect a defect in the inspection area.

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: An electron microscope includes an illuminating lens system that illuminates an electron beam that is emitted from an electron source onto a specimen as a planar illuminating electron beam having a two-dimensional spread, an imaging lens system that projects and magnifies the reflecting electron beam emitted from the specimen to project and form a specimen image, a beam separator that separates the illuminating electron beam from the reflecting electron beam, and a controller. The controller controls the reflecting electron beam so as to go straight through the beam separator, and the illuminating electron beam so as to keep a deflection angle of the illuminating electron beam which is made by the beam separator substantially constant.

Abstract: Because a mirror electron imaging type inspection apparatus for obtaining an inspection object image with mirror electrons has been difficult to optimize inspection conditions, since the image forming principles of the apparatus are different from those of conventional SEM type inspection apparatuses. In order to solve the above conventional problem, the present invention has made it possible for the user to examine such conditions as inspection speed, inspection sensitivity, etc. intuitively by displaying the relationship among the values of inspection speed S, inspection object digital signal image pixel size D, inspection object image size L, and image signal acquisition cycle P with use of a time delay integration method as a graph on an operation screen. The user can thus determine a set of values of a pixel size, an inspection image width, and a TDI sensor operation cycle easily with reference to the displayed graph.

Abstract: A defect inspection apparatus is provided which allows a technology for inspecting a pattern on a wafer by using an electron beam to implement a high-resolution and higher-speed inspection. A semiconductor wafer is irradiated with an electron beam and electrons reflected in the vicinity of the wafer are detected. The presence or absence of a defect and the location thereof are measured by forming an image from only a component which changes with a periodicity larger than a size of a circuit pattern or the repetition periodicity thereof by using lenses and comparing an image signal with a preset value.

Abstract: While an image obtained by a general electron microscope is affected by the shape and material of an object specimen, an image obtained from mirror electrons is affected by the shape of an equipotential surface on which the mirror electrons are reflected, thereby the image interpretation is complicated. A mirror electron microscope of the present invention is provided with the following means for controlling a reflecting plane of the mirror electrons according to the structure of an object pattern to be measured or a concerned defect. 1) Means for controlling a potential difference between a specimen and an electron source equivalent to a height of a reflecting plane of a mirror electron beam according to a type, an operation condition of an electron source, and a type of a pattern on a specimen. 2) Means for controlling an energy distribution of an illuminating beam with an energy filter 9 disposed in an illuminating system.

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 present invention, the structure of an electrification control electrode is changed from a grid type to a slit type and thereby shadows are not formed when a wafer is irradiated with a beam. Further, a beam forming slit is disposed ahead of an electrification control slit, thus the electrification control slit is prevented from being irradiated with an electron beam for preliminary electrification, and thereby secondary electrons which disturb the control of the electrification are inhibited from being generated. The shape of the slit is designed so that the strength of an electron beam may gradually decrease toward both the ends of an electron beam irradiation region in the longitudinal direction thereof. Furthermore, a preliminary static eliminator to remove or reduce the unevenness in an electrification potential distribution which has undesirably been formed earlier is disposed.

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: 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.