Abstract: A resin coating device for coating a surface of a glass fiber, includes: a point having a point hole; a die disposed directly below the point and including a first alignment portion, a second alignment portion, and a first die hole; and a first resin supply path. The second alignment portion is disposed below the first alignment portion. The first alignment portion includes a first diameter-reduced portion, and a first land portion disposed, connected to the first diameter-reduced portion, and having a constant diameter in the traveling direction. The second alignment portion includes a second diameter-reduced portion, and a second land portion, connected to the second diameter-reduced portion, and having a constant diameter in the traveling direction. The first diameter-reduced portion, the first land portion, the second diameter-reduced portion, and the second land portion are each a part of the first die hole.

Abstract: An optical-fiber ribbon includes a plurality of optical-fibers, and a common covering layer. There are formed a plurality of intermittent connection portions in which a first connection portion that is formed from the common covering layer and a non-connection portion are alternately formed between the optical-fibers. There are formed a plurality of continuous connection portions in which a second connection portion that is formed from the common covering layer is continuously formed between optical-fibers. The intermittent connection portions include a central intermittent connection portion at a central portion of the optical-fiber ribbon in a width direction. The continuous connection portions include adjacent continuous connection portions. A thickness of adjacent continuous connection portion is larger than a thickness of the central intermittent connection portion and is larger than a thickness of the continuous connection portion other than the adjacent continuous connection portions.

Abstract: A steel wire having a cross section perpendicular to a longitudinal direction having a flat shape, and an outer shape of the cross section including a pair of linear parts opposing each other, and a pair of curved parts opposing each other and connecting the linear parts. The curved part includes a pair of first regions located at positions near the linear parts, and a second region located at a position between the pair of first regions, a radius of curvature, R1 of the first region is greater than or equal to 0.05 mm but less than 0.15 mm, and a radius of curvature, R2 of the second region is greater than or equal to 0.13 mm but less than or equal to 0.2 mm, and an angle between the linear part and the curved part is greater than or equal to 165 degrees.

Abstract: A scanning probe microscope system capable of identifying an element with atomic scale spatial resolution comprises: an X-ray irradiation means for irradiating a measurement object with high-brilliance monochromatic X-rays having a beam diameter smaller than 1 mm; a probe arranged to oppose to the measurement object; a processing means for detecting and processing a tunneling current through the probe; and a scanning probe microscope having an alignment means for relatively moving the measurement object, the probe, and the incident position of the high-brilliance monochromatic X-rays to the measurement object.

Abstract: A scanning probe microscope system capable of identifying an element with atomic scale spatial resolution comprises: an X-ray irradiation means for irradiating a measurement object with high-brilliance monochromatic X-rays having a beam diameter smaller than 1 mm; a probe arranged to oppose to the measurement object; a processing means for detecting and processing a tunneling current through the probe; and a scanning probe microscope having an alignment means for relatively moving the measurement object, the probe, and the incident position of the high-brilliance monochromatic X-rays to the measurement object.