Abstract: Provided is a charged particle beam device or charged particle microscope permitting observation of even a large-sized specimen in the air atmosphere or a gaseous atmosphere. A charged particle beam device that adopts a thin film which partitions a vacuum atmosphere and the air atmosphere (or gaseous atmosphere) includes a charged particle optical lens barrel in which a charged particle optical system is stored, a housing in which a route along which a primary charged particle beam emitted from the charged particle optical lens barrel reaches the thin film is sustained in the vacuum atmosphere, and a mechanism that bears the charged particle optical lens barrel and first housing against a device installation surface. As the bearing mechanism, a housing having an opening through which a large-sized specimen is carried in or a mechanism having a shape other than the shape of the housing, such as, a post is adopted.

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: Provided is a circuit-pattern inspection device which enables efficient inspection of a semiconductor wafer by selectively inspecting areas on the semiconductor wafer, such as boundaries between patterns thereon, where defects are likely to occur during the step of producing the semiconductor wafer while changing the beam scanning direction for each area. Two-dimensional beam-deflection control is employed for inspection operations in a continuous-stage-movement-type circuit-pattern inspection device in which only one-dimensional scanning has been employed conventionally. That is, by employing a combination of an electron-beam-deflection control in a first direction parallel to the stage-movement direction and an electron-beam-deflection control in a second direction intersecting the stage-movement direction, it is possible to obtain an image of any desired area for inspection that is set within a swath.

Abstract: A disclosed method for observing the structure and characteristics of a specimen by an electron microscope realizes high-density charge accumulation on a specimen and improves the quality of voltage contrast images. For structural observation of a specimen and evaluation of its electrical characteristic using an electron beam, charging the specimen is performed. In this charging process, high-density charge accumulation on the specimen is achieved by irradiating the specimen with an electron beam set to have injection energy that falls within an injection energy band for which high charging efficiency is attained during electron beam irradiation and changing irradiation energy, while maintaining the injection energy.

Abstract: A semiconductor device inspection apparatus having a noise subtraction function includes an electron gun, a stage for holding a sample, a main detector for detecting a signal discharged from the sample, and at least one or more sub detector for detecting noise generated from the sample or apparatus so that there can be obtained an image in which the noise caused by discharge generated on the sample or in the apparatus is removed from the signal. The noise subtraction function subtracts the noise detected by the sub detector from the signal detected by the main detector to remove or reduce the noise from the signal.

Abstract: A charged-particle microscope device and a method of controlling charged-particle beams are provided, which are capable of signal detection at the time when the charged state of an observation sample or a defect portion becomes optimum. Charge accumulation-waiting time T from an initial irradiation with an electron beam 21 for enhancing charge accumulation on an observation sample 100 until a next irradiation with the electron beam 21 for sample observation is set depending on the state of the observation sample 100 or a defect portion 112 generated on the observation sample 100. The irradiation with the electron beam 21 for enhancing charge accumulation and the irradiation with the electron beam 21 for sample observation are performed on the observation sample 100 on the basis of the charge accumulation-waiting time T.

Abstract: An inspection system uses a scanning electron microscope that detects a high-precision electron beam image, and at the same time removes restrictions for a low sampling rate. A sampled signal is obtained by sampling an analog brightness signal generated by a secondary electron detector at a predetermined sampling rate, and contiguous digital values contained in the sampled signal are added on an N by N digital value basis to generate a digital brightness signal whose frequency is equal to 1/N of the sampling frequency. Each, digital value contained in the digital brightness signal is divided by N to generate a digital signal made of digital values having a number of bits equal to that of the sampled signal and to generate an image signal in which each digital value of the digital signal forms one pixel data.

Abstract: The present invention provides an appearance inspection apparatus that allows a user to give precedence to either defect detection performance or throughput. The appearance inspection apparatus allows a user to select the frequency of a digital image signal or the ratio of the frequency of the digital image signal to a sampling rate. Further, a user is allowed to select either throughput improvement or S/N improvement to prioritize.

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: A semiconductor device inspection apparatus having a noise subtraction function includes an electron gun, a stage for holding a sample, a main detector for detecting a signal discharged from the sample, and at least one or more sub detector for detecting noise generated from the sample or apparatus so that there can be obtained an image in which the noise caused by discharge generated on the sample or in the apparatus is removed from the signal. The noise subtraction function subtracts the noise detected by the sub detector from the signal detected by the main detector to remove or reduce the noise from the signal.

Abstract: A semiconductor device inspection apparatus having a noise subtraction function includes an electron gun, a stage for holding a sample, a main detector for detecting a signal discharged from the sample, and at least one or more sub detector for detecting noise generated from the sample or apparatus so that there can be obtained an image in which the noise caused by discharge generated on the sample or in the apparatus is removed from the signal. The noise subtraction function subtracts the noise detected by the sub detector from the signal detected by the main detector to remove or reduce the noise from the signal.

Abstract: The present invention provides an appearance inspection apparatus that allows a user to give precedence to either defect detection performance or throughput. The appearance inspection apparatus allows a user to select the frequency of a digital image signal or the ratio of the frequency of the digital image signal to a sampling rate. Further, a user is allowed to select either throughput improvement or S/N improvement to prioritize.

Abstract: An object of the present invention is to provide an inspection system using a scanning electron microscope that detects a high-precision electron beam image and at the same time, removes restrictions for a low sampling rate, which presents a problem at this point, of an AD converter element and an inspection method.

Abstract: A semiconductor device inspection apparatus having a noise subtraction function includes an electron gun, a stage for holding a sample, a main detector for detecting a signal discharged from the sample, and at least one or more sub detector for detecting noise generated from the sample or apparatus so that there can be obtained an image in which the noise caused by discharge generated on the sample or in the apparatus is removed from the signal. The noise subtraction function subtracts the noise detected by the sub detector from the signal detected by the main detector to remove or reduce the noise from the signal.