Steering system for a droplet generator in a EUV system. The steering system permits controlled positioning of a droplet release point of the droplet generator. A movable member holding the droplet generator is coupled to stationary elements of the EUV system through a coupling system having a first subsystem that constrains lateral translation of the movable member, and a second subsystem that controls a relative inclination of the movable member. The first and second subsystems preferably include one or a combination of flexures that permit highly precise and repeatable positioning.

Provided is an electron beam irradiating device capable of emitting an electron beam from an electron beam generation source surrounded by a vacuum chamber to outside of the vacuum chamber through an electron beam exit window. The electron beam exit window includes: a grid; a window foil allowing the electron beam to pass therethrough; and a frame-shaped pressing member pressing the window foil against the grid. The surface of the grid has a groove section having an annular shape. A metal gasket is pressed between the groove section and the window foil.

An x-ray collimator that may include a substrate containing a plurality of holes, each hole being frustoconical at one end and tubular at the other end for use in an x-ray imaging system, whereby the x-ray collimator may be aligned with a two-dimensional array of x-ray sources and a two-dimensional x-ray sensor, and whereby x-ray photons from the x-ray sources may pass through the collimator holes and emerge as a beam of x-ray photons in a narrow angle cone which may pass through a subject being imaged, positioned between the output holes of the collimator and the x-ray sensor.

According to one embodiment, a method, computer system, and computer program product for smoothing one or more surfaces of a 3D-printed object in reduced gravity is provided. The present invention may include positioning one or more radiative heating elements to evenly heat one or more surfaces of a 3D-printed object based on a shape of the 3D-printed object; determining, for at least one of the one or more radiative heating elements, a desired heat output necessary to melt the outermost layers of the one or more surfaces; and pulsing the one or more radiative heating elements to melt the one or more surfaces, wherein the duration and frequency of the pulsing is configured to achieve the desired heat output.

Methods of marking paper products and marked paper products are provided. Some methods include irradiating the paper product to alter the functionalization of the paper.

Methods of marking paper products and marked paper products are provided. Some methods include irradiating the paper product to alter the functionalization of the paper.

A charged particle beam treatment apparatus includes an accelerator that emits a charged particle beam by accelerating a charged particle, an irradiation unit that irradiates an irradiation target body with the charged particle beam, a beam transport line that connects the accelerator and the irradiation unit to each other, and that transports the charged particle beam from the accelerator to the irradiation unit, and a control unit that controls the irradiation unit in irradiating the irradiation target body with the charged particle beam. The irradiation unit includes a scanning unit that scans each layer with the charged particle beam. After one layer is scanned with the charged particle beam by using a first current value, the control unit controls the irradiation unit so as to scan and irradiate the one layer with the charged particle beam by using a second current value which is different from the first current value.

A charged particle beam treatment apparatus includes an accelerator that emits a charged particle beam by accelerating a charged particle, an irradiation unit that irradiates an irradiation target body with the charged particle beam, a beam transport line that connects the accelerator and the irradiation unit to each other, and that transports the charged particle beam from the accelerator to the irradiation unit, and a control unit that controls the irradiation unit in irradiating the irradiation target body with the charged particle beam. The irradiation unit includes a scanning unit that scans each layer with the charged particle beam. After one layer is scanned with the charged particle beam by using a first current value, the control unit controls the irradiation unit so as to scan and irradiate the one layer with the charged particle beam by using a second current value which is different from the first current value.

An apparatus includes a support and a radioactive source on the support. The radioactive source includes nuclei. An excitation element is coupled to the support. Upon activation of the excitation element, radiation emission from the radioactive source is reduced. The excitation element includes a vibration source. Excitation is transferred from nuclei of the radioactive source to nuclei of the support. The excitation transfer occurs in bulk from multiple nuclei of the radioactive source. The excitation transfer causes emissions from the support.

An apparatus includes a support and a radioactive source on the support. The radioactive source includes nuclei. An excitation element is coupled to the support. Upon activation of the excitation element, radiation emission from the radioactive source is reduced. The excitation element includes a vibration source. Excitation is transferred from nuclei of the radioactive source to nuclei of the support. The excitation transfer occurs in bulk from multiple nuclei of the radioactive source. The excitation transfer causes emissions from the support.