According to one embodiment, an inspection apparatus includes an irradiation device irradiating an inspection target substrate with multiple beams, a detector detecting each of a plurality of charged particle beams formed by charged particles emitted from the inspection target substrate as an electrical signal, and a comparison processing circuitry performing pattern inspection by comparing image data of a pattern formed on the inspection target substrate, the pattern being reconstructed in accordance with the detected electrical signals, and reference image data. The detector includes a plurality of detection elements that accumulate charges, and a detection circuit that reads out the accumulated charges. The plurality of detection elements are grouped into a plurality of groups. The detection circuit operates in a manner of, during a period in which the charged particle beams are applied to the detection elements included in one group, reading out the charges accumulated in the detection elements included in one or more other groups.

A monitoring device includes a filtering section that extracts and outputs at least one of a high frequency component or a low frequency component of a beam current received from a detection output section of an ion implantation device; and a computation section that computes at least one of a value corresponding to a content ratio of the high frequency component in the beam current, or a value corresponding to a content ratio of the low frequency component in the beam current.

Disclosed herein is a method comprising: generating a plurality of probe spots on a sample by a plurality of beams of charged particles; while scanning the plurality of probe spots across a region on the sample, recording from the plurality of probe spots a plurality of sets of signals respectively representing interactions of the plurality of beams of charged particles and the sample; generating a plurality of images of the region respectively from the plurality of sets of signals; and generating a composite image of the region from the plurality of images.

A plasma processing apparatus performs a stable and accurate matching operation with high reproducibility in a power modulation process of modulating of a high frequency power to be supplied into a processing vessel in a pulse shape. In the plasma processing apparatus, an impedance sensor 96A provided in a matching device performs a dual sampling averaging process on a RF voltage measurement value and an electric current measurement value respectively obtained from a RF voltage detector 100A of a voltage sensor system and a RF electric current detector 108A of an electric current sensor system by sampling-average-value calculating circuits 104A and 112A and by moving-average-value calculating circuits 106A and 114A. Thus, an update speed of a load impedance measurement value outputted from the impedance sensor 96A can be matched well with a driving control speed of a motor in a matching controller.

An electron microscope and method of operating an electron microscope (1) has an electron beam source (11) for producing an electron beam, a noise canceling aperture (12) for detecting a part of the beam, an amplifier (42), an effective value calculating circuit (44) for extracting DC components of the output signal from the amplifier (42), a detector (15) for detecting a signal obtained in response to impingement of the beam on a sample (A), a preamplifier circuit (20), an amplifier circuit (30), a dividing circuit (54) for performing a division based on the output signal from the amplifier circuit (30) and on the output signal from the amplifier (42), and a multiplier circuit (58) for performing multiplication of the output signal from the dividing circuit (54) and the output from the effective value calculating circuit (44).

A scanning electron microscope includes: a retarding power source configured to apply a retarding voltage to a specimen; a combined objective lens configured to focus the primary beam on a surface of the specimen; an electrostatic deflection system configured to deflect the primary beam to direct the primary beam to each point in a field of view on the surface of the specimen; a first scintillation detector having a first scintillator configured to emit light upon incidence of secondary electrons which have been emitted from the specimen; a Wien filter configured to deflect the secondary electrons in one direction without deflecting the primary beam; and a second scintillation detector having a second scintillator configured to detect the secondary electrons deflected by the Wien filter. The second scintillator has a distal end located away from the axis of the primary beam.

A scanning electron microscope incorporates a multi-pixel solid-state electron detector. The multi-pixel solid-state detector may detect back-scattered and/or secondary electrons. The multi-pixel solid-state detector may incorporate analog-to-digital converters and other circuits. The multi-pixel solid state detector may be capable of approximately determining the energy of incident electrons and/or may contain circuits for processing or analyzing the electron signals. The multi-pixel solid state detector is suitable for high-speed operation such as at a speed of about 100 MHz or higher. The scanning electron microscope may be used for reviewing, inspecting or measuring a sample such as unpatterned semiconductor wafer, a patterned semiconductor wafer, a reticle or a photomask. A method of reviewing or inspecting a sample is also described.

The present invention relates to modulating an irradiation condition of a charged particle beam at high speed and detecting a signal in synchronization with a modulation period for the purpose of extracting a signal arising from a certain charged particle beam when a sample is irradiated with a plurality of charged particle beams simultaneously or, for example, for the purpose of separating a secondary electron signal arising from ion beam irradiation and a secondary electron signal arising from electron beam irradiation in an FIB-SEM system. The present invention further relates to dispersing light emitted from two or more kinds of scintillators having different light emitting properties, detecting each signal strength, and processing a signal on the basis of a ratio of first signal strength when the sample is irradiated with a first charged particle beam alone to second signal strength when the sample is irradiated with a second charged particle beam alone, the ratio being set by a mechanism. The present invention enables extraction of only a signal arising from a desired charged particle beam even when the sample is irradiated with the plurality of charged particle beams simultaneously. The SEM observation can be performed in the middle of the FIB processing using the secondary electron in the FIB-SEM system, for example.

The disclosure relates to a method of imaging a specimen using a transmission charged particle microscope, said method comprising providing a specimen, and providing a charged particle beam and directing said charged particle beam onto said specimen for generating a flux of charged particles transmitted through the specimen. The method comprises the step of generating and recording a first energy filtered flux of charged particles transmitted through the specimen, wherein said first energy filtered flux of charged particles substantially consists of non-scattered and elastically scattered charged particles. The method as disclosed herein comprises the further step of generating and recording a second energy filtered flux of charged particles transmitted through the specimen, wherein said second energy filtered flux of charged particles substantially consists of inelastically scattered charged particles. Said first and second recorded energy filtered flux are then used for imaging said specimen with increased contrast.

Provided is a charged particle beam device capable of detecting signal charged particles in a wide range of elevation angles from a large elevation angle to a small elevation angle and distinguishing detection signals between backscattered charged particles and secondary charged particles regardless of distribution of the signal charged particles. The charged particle beam device according to the disclosure includes a first detector that detects the secondary charged particles or the backscattered charged particles and a second detector that detects tertiary charged particles generated from the first detector, and generates an observation image of a sample using a signal value obtained by subtracting at least a part of a second detection signal output by the second detector from a first detection signal output by the first detector, or subtracting at least a part of the first detection signal from the second detection signal.