Provided herein are portable ultraviolet (UV) devices, systems, and methods of use and manufacturing same. Methods of use include methods for UV disinfection and sterilization, more specifically, methods for UV disinfection and sterilization of a container, a room, a space or a defined environment. The portable UV devices, systems and methods are particularly useful for the UV disinfection and sterilization of a container, a room, a space or defined environment used in various industries. Provided are also portable UV devices, systems, and methods for inhibiting the growth of one or more species of microorganisms present in a container, a room, a space or a defined environment, preferably for inhibiting the growth of one or more species of microorganisms present on an interior surface of a container, a room, a space or a defined environment.

The invention relates to Transmission Charged Particle Beam (TCPB) apparatus comprising a sample holder, for holding a sample, a source for producing a beam of charged particles and an illuminator for directing said beam so as to irradiate the sample; The TCPB apparatus comprises an imaging system, for receiving a flux of charged particles transmitted through the sample and directing it onto a sensing device. Further, a controller is provided for controlling at least some operational aspects of the TCPB apparatus. As defined herein, the controller is arranged for receiving calibration data of said TCPB apparatus and using said calibration data for optically aligning said TCPB apparatus. Said calibration data may be obtained in a calibration session, wherein different settings for eucentric focus can be used as a measure of eucentric height, so that the TCPB apparatus can be optically aligned in absence of a sample on the sample holder.

An electron beam inspection apparatus, the apparatus including a plurality of electron beam columns, each electron beam column configured to provide an electron beam and detect scattered or secondary electrons from an object, and an actuator system configured to move one or more of the electron beam columns relative to another one or more of the electron beam columns. The actuator system may include a plurality of first movable structures at least partly overlapping a plurality of second movable structures, the first and second movable structures supporting the plurality of electron beam columns.

Provided is a mirror device including a mirror which is supported to be flappable around a fast axis and supported to be flappable around a slow axis and in which a resonance frequency of flapping thereof with respect to the fast axis is a first value and a resonance frequency of the flapping thereof with respect to the slow axis is a second value lower than the first value; a signal extracting portion configured to obtain from a slow axis coil a synthesized signal including an induced signal generated in the slow axis coil due to an operation of flapping the mirror around the fast axis and configured to extract the induced signal from the synthesized signal; and a signal generating portion configured to generates a driving signal so that the flapping of the mirror with respect to the fast axis is in a resonance state according to the induced signal.

An etching apparatus includes a substrate holder configured to hold a substrate, a first ion source that generates first ions and irradiates the substrate with the first ions such that the first ions are incident on the substrate in the substrate holder at a first incident angle, and a second ion source that generates second ions and irradiates the substrate with the second ions such that the second ions are incident on the substrate at a second incident angle different from the first incident angle. A controller is provided that controls at least one of the first incident angle and the second incident angle by moving at least one of the first ion source and the second ion source.

A radiation analysis apparatus includes an excitation source unit irradiating an object, for which the radiation analysis apparatus analyzes property or a structure, with a first radiation, a radiation detection unit including three or more radiation detectors that detect a second radiation generated from the object irradiated with the first radiation, a radiation focusing unit disposed between the object and the radiation detection unit, and focusing the second radiation, a position changing unit changing a relative positional relationship between the radiation focusing unit and the radiation detection unit, and a control unit controlling the position changing unit to change the positional relationship, based on first information which is stored in a storage unit and indicates an intensity distribution of the second radiation emitted from the radiation focusing unit and second information indicating a distribution based on a detection count of the second radiation detected by each of the radiation detectors.

A vacuum condition processing apparatus is provided, the top of which is connected to an external charged particle beam generating device, and the apparatus includes: a suction cup in contact with the specimen to be observed or the stage holding the specimen, a first gas controlling device connected to an external gas supplying system, and a second gas controlling device connected to an external pumping system; a window is deployed at the top of the apparatus, through which the particle beam can go into the apparatus; the first gas controlling device is arranged to connect the gas supplying system and the suction cup; the second gas controlling device is arranged to connect the gas pumping system and the suction cup. Also disclosed is a specimen observation system and method.

Provided is a mirror device including a mirror which is supported to be flappable around a fast axis and supported to be flappable around a slow axis and in which a resonance frequency of flapping thereof with respect to the fast axis is a first value and a resonance frequency of the flapping thereof with respect to the slow axis is a second value lower than the first value; a signal extracting portion configured to obtain from a slow axis coil a synthesized signal including an induced signal generated in the slow axis coil due to an operation of flapping the mirror around the fast axis and configured to extract the induced signal from the synthesized signal; and a signal generating portion configured to generates a driving signal so that the flapping of the mirror with respect to the fast axis is in a resonance state according to the induced signal.

Provided is a mirror device including a mirror which is supported to be flappable around a fast axis and supported to be flappable around a slow axis and in which a resonance frequency of flapping thereof with respect to the fast axis is a first value and a resonance frequency of the flapping thereof with respect to the slow axis is a second value lower than the first value; a signal extracting portion configured to obtain from a slow axis coil a synthesized signal including an induced signal generated in the slow axis coil due to an operation of flapping the mirror around the fast axis and configured to extract the induced signal from the synthesized signal; and a signal generating portion configured to generates a driving signal so that the flapping of the mirror with respect to the fast axis is in a resonance state according to the induced signal.

Provided herein are portable ultraviolet (UV) devices, systems, and methods of use and manufacturing same. Methods of use include methods for UV disinfection and sterilization, more specifically, methods for UV disinfection and sterilization of a container, a room, a space or a defined environment. The portable UV devices, systems and methods are particularly useful for the UV disinfection and sterilization of a container, a room, a space or defined environment used in various industries. Provided are also portable UV devices, systems, and methods for inhibiting the growth of one or more species of microorganisms present in a container, a room, a space or a defined environment, preferably for inhibiting the growth of one or more species of microorganisms present on an interior surface of a container, a room, a space or a defined environment.