A processing system for forming a cross-section of an object. The processing system comprises a focused ion beam system for forming the cross-section from a pre-prepared surface region of the object and a laser and a light optical system for forming the pre-prepared surface region by laser ablation of a processing region of the object with a first and a second laser beam. The light optical system is configured to direct the first and the second laser beams onto common impingement locations of a common scanning line in the processing region for scanning the first laser beam and for scanning the second laser beam. For each of the impingement locations, an angle between a first incidence direction along an axis of the first laser beam and a second incidence direction along an axis of the second laser beam is greater than 10 degrees, measured in a stationary coordinate system.

A processing system for forming a cross-section of an object. The processing system comprises a focused ion beam system for forming the cross-section from a pre-prepared surface region of the object and a laser and a light optical system for forming the pre-prepared surface region by laser ablation of a processing region of the object with a first and a second laser beam. The light optical system is configured to direct the first and the second laser beams onto common impingement locations of a common scanning line in the processing region for scanning the first laser beam and for scanning the second laser beam. For each of the impingement locations, an angle between a first incidence direction along an axis of the first laser beam and a second incidence direction along an axis of the second laser beam is greater than 10 degrees, measured in a stationary coordinate system.

An additive manufacturing system including a two-dimensional energy patterning system for imaging a powder bed is disclosed. Improved structure formation, part creation and manipulation, use of multiple additive manufacturing systems, and high throughput manufacturing methods suitable for automated or semi-automated factories are also disclosed.

An additive manufacturing system including a two-dimensional energy patterning system for imaging a powder bed is disclosed. Improved structure formation, part creation and manipulation, use of multiple additive manufacturing systems, and high throughput manufacturing methods suitable for automated or semi-automated factories are also disclosed.

Methods for stripping an optical fiber coating using blue or blue-violet radiation are disclosed. The method includes irradiating a portion of the coating with at least one radiation beam having a processing wavelength in the range of 400 nm to 460 nm for which the coating is substantially transparent. The intensity of the radiation beam exceeds the optical-damage threshold of the coating, and thereby a damaged coating portion that absorbs radiation at the processing wavelength is formed. The damaged coating portion is then irradiated with the radiation beam having an intensity below the optical-damage threshold to cause the damaged coating portion to absorb the radiation and to subsequently heat up and disintegrate to expose a section of the central glass portion of the optical fiber.

Methods for stripping an optical fiber coating using blue or blue-violet radiation are disclosed. The method includes irradiating a portion of the coating with at least one radiation beam having a processing wavelength in the range of 400 nm to 460 nm for which the coating is substantially transparent. The intensity of the radiation beam exceeds the optical-damage threshold of the coating, and thereby a damaged coating portion that absorbs radiation at the processing wavelength is formed. The damaged coating portion is then irradiated with the radiation beam having an intensity below the optical-damage threshold to cause the damaged coating portion to absorb the radiation and to subsequently heat up and disintegrate to expose a section of the central glass portion of the optical fiber.

A method of making a light weight component is provided. The method including the steps of: forming a metallic foam core into a desired configuration; applying an external metallic shell to an exterior surface of the metallic foam core after it has been formed into the desired configuration; forming an inlet opening and an outlet opening in the external metallic shell in order to provide a fluid path through the metallic foam core; and injecting a thermoplastic material into the metallic foam core via the inlet opening.

A method of making a light weight housing for an internal component is provided. The method including the steps of: forming a first metallic foam core into a desired configuration; forming a second metallic foam core into a desired configuration; inserting an internal component into the first metallic foam core; placing the second metallic foam adjacent to the first metallic core in order to secure the internal component between the first metallic foam core and the second metallic foam core; and applying an external metallic shell to an exterior surface of the first metallic foam core and the second metallic foam core.

A method of making a light weight component is provided. The method including the steps of: forming a metallic foam core into a desired configuration; applying an external metallic shell to an exterior surface of the metallic foam core after it has been formed into the desired configuration; and attenuating the component to a desired frequency by forming a plurality of openings in the external metallic shell.

A method of making a light weight component is provided. The method including the steps of: forming a metallic foam core into a desired configuration; applying an external metallic shell to an exterior surface of the metallic foam core after it has been formed into the desired configuration; and attenuating the component to a desired frequency by forming a plurality of openings in the external metallic shell.