Abstract: A timepiece provided with a metal case having a fitting section which is annularly provided in a lower portion of the inner circumferential surface, a metal lid body having a lid main body section which is arranged on a lower end of the case and covers a lower portion of the case and a cylindrical section which is arranged in the fitting section of the case, and a synthetic resin gasket having a gasket main body section which is arranged between the fitting section of the case and the cylindrical section of the lid body and a spacer section which forms a space between a lower end surface of the case and an upper surface of the lid main body section.

Abstract: A surface-enhanced Raman scattering unit comprises a measurement board used upon measurement; a surface-enhanced Raman scattering element, secured to the measurement board, having a substrate and an optical function part, formed on the substrate, for generating surface-enhanced Raman scattering; and a pressing member, secured to the measurement board, having a ring-shaped contact part contacting a peripheral part of the surface-enhanced Raman scattering element and pressing the surface-enhanced Raman scattering element toward the measurement board.

Abstract: A SERS unit 1A comprises a SERS element 2 having a substrate 21 and an optical function part 20 formed on the substrate 21, the optical function part 20 for generating surface-enhanced Raman scattering; a transportation board 3 supporting the SERS element 2 during transportation, the SERS element 2 being removed from the transportation board 3 upon measurement; and a holding part 4 having a pinching part 41 pinching the SERS element 2 in cooperation with the transportation board 3, and detachably holding the SERS element 2 in the transportation board 3.

Abstract: A method for making a surface enhanced Raman scattering device in accordance with one aspect of the present invention comprises a first step of forming a nanoimprint layer on a main surface of a wafer including a plurality of portions each corresponding to a substrate; a second step of transferring, by using a mold having a pattern corresponding to a fine structural part, the pattern to the nanoimprint layer after the first step, and thereby forming the formed layer including the fine structural part for each portion corresponding to the substrate; a third step of forming a conductor layer on the fine structural part after the second step; and a fourth step of cutting the wafer into each portion corresponding to the substrate after the second step.

Abstract: A SERS element comprises a substrate; a fine structure part formed on a front face of the substrate and having a plurality of pillars; and a conductor layer formed on the fine structure part and constituting an optical function part for generating surface-enhanced Raman scattering. The pillars have respective side faces provided with grooves. A plurality of gaps are formed in the conductor layer by entering the grooves.

Abstract: A watch case having a through-hole, an operating member including an operating shaft to be inserted to the through-hole of the watch case, an exterior member mounted on the operating member and configured to be displaced in a shaft direction of the operating shaft and be rotated together with the operating member, and a buffer member located between the operating member and the exterior member are provided. Therefore, when the exterior member receives impact from outside, the impact can be buffered by the buffer member. As a result, the operating member can be prevented from being damaged because the impact from the outside is not directly transmitted to the operating member, thereby improving impact resistance.

Abstract: A SERS element 2 comprises a substrate 21 having a front face 21a; a fine structure part 24, formed on the front face 21a, having a plurality of pillars 27; a first conductor layer 31 formed on the front face 21a and fine structure part 24 so as to cover the front face 21a and fine structure part 24 continuously; and a second conductor layer 32 formed on the first conductor layer 31 so as to form a plurality of gaps G1, G2 for surface-enhanced Raman scattering; while the first and second conductor layers 31, 32 are constituted by the same material.

Abstract: A surface-enhanced Raman scattering element comprises a substrate having a principal surface; a molded layer having a support part formed on the principal surface of the substrate so as to extend along the principal surface and a fine structure part formed on the support part; a frame part formed on the principal surface of the substrate so as to surround the support part and fine structure part along the principal surface; and a conductor layer formed on at least the fine structure part and constituting an optical functional part for generating surface-enhanced Raman scattering; while the fine structure part are formed integrally with the support part.

Abstract: A SERS unit comprises an integrally formed handling board and a SERS element secured within a container space provided in the handling board so as to open to one side in a thickness direction of the handling board. The SERS element has a substrate arranged on an inner surface of the container space and an optical function part formed on the substrate, for generating surface-enhanced Raman scattering.

Abstract: A surface-enhanced Raman scattering element comprises a substrate having a principal surface; a molded layer having a support part formed on the principal surface of the substrate so as to extend along the principal surface and a fine structure part formed on the support part; and a conductor layer formed on the fine structure part and constituting an optical functional part for generating surface-enhanced Raman scattering; the molded layer being relatively thinner in a direction intersecting the principal surface of the substrate at a center edge part of a fine structure area formed with the fine structure part in the molded layer than at an outer edge part of the fine structure area.

Abstract: A SERS element comprises a substrate having a front face; a fine structure part formed on the front face and having a plurality of pillars; and a conductor layer formed on the fine structure part and constituting an optical function part for generating surface-enhanced Raman scattering. The conductor layer has a base part formed along the front face and a plurality of protrusions protruding from the base part at respective positions corresponding to the pillars. The base part has a thickness greater than the height of the pillars.

Abstract: A SERS element comprises a substrate; a fine structure part formed on a front face of the substrate and having a plurality of pillars; and a conductor layer formed on the fine structure part and constituting an optical function part for generating surface-enhanced Raman scattering. The conductor layer has a base part formed along the front face of the substrate and a plurality of protrusions protruding from the base part at respective positions corresponding to the pillars. The base part and the protrusions form a plurality of gaps in the conductor layer, each of the gaps having an interstice gradually decreasing in the projecting direction of the pillar.

Abstract: A surface-enhanced Raman scattering element comprises a substrate having a principal surface; a molded layer including a support part formed on the principal surface and a fine structure part formed on the support part; and a conductor layer, deposited on the fine structure part, constituting an optical functional part for generating surface-enhanced Raman scattering. The fine structure part has a plurality of pillars erected on the support part. The support part is provided with a plurality of opposing parts opposing side faces of the pillars. The opposing parts are located on the substrate side relative to leading end parts of the pillars in a projecting direction of the pillars.

Abstract: A surface-enhanced Raman scattering element comprises a substrate having a principal surface; a molded layer having a support part formed on the principal surface of the substrate so as to extend along the principal surface and a fine structure part formed on the support part; and a conductor layer formed on the fine structure part and constituting an optical functional part for generating surface-enhanced Raman scattering; the molded layer being relatively thinner in a direction intersecting the principal surface of the substrate at an outer edge part of a fine structure area formed with the fine structure part in the molded layer than at a center part of the fine structure area.

Abstract: A SERS element comprises a substrate; a fine structure part formed on a front face of the substrate and having a plurality of pillars; and a conductor layer formed on the fine structure part and constituting an optical function part for generating surface-enhanced Raman scattering. The conductor layer has a base part formed along the front face of the substrate and a plurality of protrusions protruding from the base part at respective positions corresponding to the pillars. The base part and the protrusions form a plurality of gaps in the conductor layer, each of the gaps having an interstice gradually decreasing in a direction perpendicular to the projecting direction of the pillar.