Object

Provided is a medical implant having favorable biocompatibility.

Solution to Problem

An implant used for binding to a biological tissue including bone or teeth, and made of metal selected from titanium or titanium alloys, cobalt chrome alloys, and tantalum, includes a surface layer portion of a portion, which is bound to a biological tissue including bone or teeth, of the implant, the surface layer portion having a porous structure. The porous structure includes a trunk hole formed in a thickness direction and including an opening on a binding face side, open holes each constituted of a branch hole formed extending from an inner wall surface of the trunk hole in a direction different from that of the trunk hole, an interior space formed in the thickness direction and not including an opening on the binding face side, a tunnel connecting path connecting the open holes and the interior space, and a tunnel connecting path connecting the open holes.

A method for fabricating MAS NMR rotors and drive caps made of diamond to increase the maximum achievable spinning frequency and enhance MAS NMR sensitivity and resolution. Diamond is an excellent choice for making MAS NMR rotors due to its high tensile and flexural strength, however, micromachining diamond is difficult due to its hardness. Although laser cutting is often employed to cut diamond sheets, this process cannot be used to create the high aspect ratio and small features required for MAS NMR rotors. In the present invention, a laser micromachining process is used to create the desired high aspect ratio while maintaining the small lateral features. In this process, the laser is used to first convert the diamond into graphite followed by a conversion to carbon dioxide in the presence of oxygen. To create a rotor, a rectangular log has a center hole drilled by the laser, and is then micromachined into a hollow cylinder.

A method for fabricating MAS NMR rotors and drive caps made of diamond to increase the maximum achievable spinning frequency and enhance MAS NMR sensitivity and resolution. Diamond is an excellent choice for making MAS NMR rotors due to its high tensile and flexural strength, however, micromachining diamond is difficult due to its hardness. Although laser cutting is often employed to cut diamond sheets, this process cannot be used to create the high aspect ratio and small features required for MAS NMR rotors. In the present invention, a laser micromachining process is used to create the desired high aspect ratio while maintaining the small lateral features. In this process, the laser is used to first convert the diamond into graphite followed by a conversion to carbon dioxide in the presence of oxygen. To create a rotor, a rectangular log has a center hole drilled by the laser, and is then micromachined into a hollow cylinder.

A through-glass via hole formation method, includes: an internal deformation region formation step in which an internal deformation region is formed inside a glass substrate at a predetermined distance from a surface of the glass substrate; a surface etching step in which the glass substrate is thinned by immersing the glass substrate in an etching solution such that a portion of the surface of the glass substrate, at which the internal deformation region is not formed, is etched and removed at a first etching rate; and a through-glass via hole formation step in which, with the glass substrate immersed in the etching solution, the internal deformation region is etched and removed at a second etching rate higher than the first etching rate such that a through-glass via hole is formed in the glass substrate along the internal deformation region.

A glass plate, containing: a first main surface and a second main surface opposite to each other, wherein an in-plane void region having a plurality of voids is arranged on the first main surface, a plurality of internal void rows each having one void or two or more voids are arranged from the in-plane void region toward the second main surface, and a cut surface obtained by cutting the glass plate to pass through the in-plane void region and the plurality of internal void rows has a compressive stress layer formed by applying a chemical strengthening treatment in the center of the cut surface.

A glass plate, containing: a first main surface and a second main surface opposite to each other, wherein an in-plane void region having a plurality of voids is arranged on the first main surface, a plurality of internal void rows each having one void or two or more voids are arranged from the in-plane void region toward the second main surface, and a cut surface obtained by cutting the glass plate to pass through the in-plane void region and the plurality of internal void rows has a compressive stress layer formed by applying a chemical strengthening treatment in the center of the cut surface.

An object of one embodiment of the invention is to process a material simply and high efficiently.

A fabrication method of transparent material is a method of processing a thermosetting transparent material. The fabrication method of transparent material includes a disposing step (S01) of disposing an uncured thermosetting transparent material, a laser beam irradiation step (S02) of irradiating the disposed uncured thermosetting transparent material with a laser beam so that cavitation bubbles are generated in the uncured thermosetting transparent material, and a curing step (S03) of performing a curing process on the uncured thermosetting transparent material in which the cavitation bubbles are generated.

An object of one embodiment of the invention is to process a material simply and high efficiently.

A fabrication method of transparent material is a method of processing a thermosetting transparent material. The fabrication method of transparent material includes a disposing step (S01) of disposing an uncured thermosetting transparent material, a laser beam irradiation step (S02) of irradiating the disposed uncured thermosetting transparent material with a laser beam so that cavitation bubbles are generated in the uncured thermosetting transparent material, and a curing step (S03) of performing a curing process on the uncured thermosetting transparent material in which the cavitation bubbles are generated.

A laser device according to one embodiment of the present disclosure includes a light source and a reflection-type polarizer. The light source causes laser light to oscillate. The reflection-type polarizer is disposed on an optical path of the laser light and has a transmission axis coinciding with a polarization direction of the laser light.

A glass plate production method includes (1) preparing a glass material having a first main surface and a second main surface opposite to each other; (2) irradiating the first main surface of the glass material with a laser to form an in-plane void region having a plurality of voids arranged on the first main surface, and forming a plurality of internal void rows each having one void or two or more voids arranged from the in-plane void region toward the second main surface of the glass material; and (3) chemically strengthening the glass material having the internal void rows formed therein.