The present disclosure describes an image forming element having a semiconductor chip with micro-electro-mechanical-system (MEMS) devices and voltage generators, each voltage generator being configured to generate a voltage used by one or more of the MEMS devices. A floating ground may be used to add a voltage to the voltage generated by the voltage generators. The semiconductor chip may include electrical connections, where each voltage generator is configured to provide the voltage to the one or more MEMS devices through the electrical connections. The MEMS devices may define a boundary in the semiconductor chip within which the MEMS devices, the voltage generators, and the electrical connections are located. Each MEMS device may generate an electrostatic field to manipulate an electron beamlet of a multi-beam charged particle microscope. The MEMS devices may be organized into groups based on a distance to a reference location (e.g., optical axis) in the semiconductor chip.

A method for processing an object, with material being removed from the object, includes directing a particle beam on the object so that a location of incidence of the particle beam on the object carries out a movement along a principal scanning path and a movement along a sub-scanning direction oriented transverse to the principal scanning path. The movement of the location of incidence of the particle beam along the sub-scanning direction is controlled on the basis of a reference signal and a detection signal. The method also includes modulating the directing of the particle beam in accordance with the reference signal, and detecting secondary particles and producing the detection signal, which represents an intensity of the detected secondary particles. Controlling the movement of the location of incidence of the particle beam along the sub-scanning direction is implemented using the principle of homodyne detection.

Provided is a charged particle beam device to enable determination of a noise source of a charged particle beam device that can cause a noise frequency component superimposed on a measurement image. The charged particle beam device includes a unit that extracts information regarding a noise source. The unit that extracts information regarding a noise source includes: a control signal monitoring unit that observes a control signal of a control unit which controls an electron optical system of the charged particle beam device and outputs the observed signal; a first frequency conversion processing unit that executes frequency conversion processing on the signal output from the control signal monitoring unit; a second frequency conversion processing unit that executes frequency conversion processing on an image signal output from a detector of the electron optical system; and a frequency analysis and comparison processing unit that receives an output signal of the first frequency conversion processing unit and an image signal of the second frequency conversion processing unit, and associates a peak frequency of a superimposed noise of the image signal with a noise source of the control unit which generates a noise having a peak frequency corresponding to the peak frequency of the superimposed noise within the image signal.

A charged particle beam lithography apparatus, includes a plurality of multiple-beam sets, each of which including a plurality of irradiation sources each generating an independent charged particle beam, a plurality of objective deflectors, each arranged for a corresponding charged particle beam, and configured to deflect the corresponding charged particle beam to a desired position on a substrate, and a plurality of electrostatic or electromagnetic lens fields each to focus the corresponding charged particle beam on the target object; a plurality of common deflection amplifiers, arranged for each multiple-beam set, and each of the plurality of common deflection amplifiers being configured to commonly control the plurality of objective deflectors arranged in a same multiple-beam set; a plurality of individual ON/OFF mechanisms configured to individually turn ON/OFF a beam irradiated from each irradiation source; and one or more multiple-beam clusters including the plurality of multiple-beam sets.

A charged particle beam device includes an electron source which generates an electron beam, an objective lens which is applied with a coil current to converge the electron beam on a sample, a control unit which controls the current to be applied to the objective lens, a hysteresis characteristic storage unit which stores hysteresis characteristic information of the objective lens, a history information storage unit which stores history information related to the coil current, and an estimation unit which estimates a magnetic field generated by the objective lens on the basis of the coil current, the history information, and the hysteresis characteristic information.

A charged particle beam lithography apparatus, includes a plurality of multiple-beam sets, each of which including a plurality of irradiation sources each generating an independent charged particle beam, a plurality of objective deflectors, each arranged for a corresponding charged particle beam, and configured to deflect the corresponding charged particle beam to a desired position on a substrate, and a plurality of electrostatic or electromagnetic lens fields each to focus the corresponding charged particle beam on the target object; a plurality of common deflection amplifiers, arranged for each multiple-beam set, and each of the plurality of common deflection amplifiers being configured to commonly control the plurality of objective deflectors arranged in a same multiple-beam set; a plurality of individual ON/OFF mechanisms configured to individually turn ON/OFF a beam irradiated from each irradiation source; and one or more multiple-beam clusters including the plurality of multiple-beam sets.

Systems and methods of observing a sample in a multi-beam apparatus are disclosed. A multi-beam apparatus may comprise an array of deflectors configured to steer individual beamlets of multiple beamlets, each deflector of the array of deflectors having a corresponding driver configured to receive a signal for steering a corresponding individual beamlet. The apparatus may further include a controller having circuitry to acquire profile data of a sample and to control each deflector by providing the signal to the corresponding driver based on the acquired profile data, and a steering circuitry comprising the corresponding driver configured to generate a driving signal, a corresponding compensator configured to receive the driving signal and a set of driving signals from other adjacent drivers associated with adjacent deflectors and to generate a compensation signal to compensate a corresponding deflector based on the driving signal and the set of driving signals.

A charged particle beam lithography apparatus, includes a plurality of multiple-beam sets, each of which including a plurality of irradiation sources each generating an independent charged particle beam, a plurality of objective deflectors, each arranged for a corresponding charged particle beam, and configured to deflect the corresponding charged particle beam to a desired position on a substrate, and a plurality of electrostatic or electromagnetic lens fields each to focus the corresponding charged particle beam on the target object; a plurality of common deflection amplifiers, arranged for each multiple-beam set, and each of the plurality of common deflection amplifiers being configured to commonly control the plurality of objective deflectors arranged in a same multiple-beam set; a plurality of individual ON/OFF mechanisms configured to individually turn ON/OFF a beam irradiated from each irradiation source; and one or more multiple-beam clusters including the plurality of multiple-beam sets.

There is provided a charged particle beam apparatus including: a charged particle source; a condenser lens and an object lens for converging a charged particle beam from the charged particle source and irradiating the converged charged particle beam to a specimen; and plural image shift deflectors for deflecting the charged particle beam. In the charged particle beam apparatus, the deflection of the charged particle beam is controlled using first control parameters that set the optical axis of a charged particle beam to a first optical axis that passes through the center of the object lens and enters a predefined position of the specimen, and second control parameters that transform the first control parameters so that the first control parameters set the optical axis of the charged particle beam to a second optical axis having a predefined incident angle different from the incident angle of the first optical axis.

The invention provides an electron-impact ion source device having high brightness as compared to known Nier-type ion sources, while providing similar advantages in terms of flexibility of the generated ion species, for example. The ionization chamber of the device operates at high pressures and provides for a large number of interactions between the electron beam and the gas molecules.