Abstract: Disclosed herein is a fine and thick wiring drawn at high speed in such a manner that a region on the substrate, on which region the liquid droplet is scheduled to impact, is heated beforehand, and that immediately after the impact of the liquid droplet on the substrate, the liquid droplet is promptly solidified so as thereby to suppress the spread of the liquid droplet due to the wettability of the liquid droplet to the substrate, and also to suppress the clogging of the nozzle due to the heating of the substrate. Thereby, even in the case where a liquid droplet having a larger volume than before is used, high-speed drawing of a thick and fine wiring having a line width approximately equal to the liquid droplet size is realized independently of the substrate material.

Abstract: A method of adjusting a resonance frequency in an optical scanning device containing: providing the optical scanning device having a substrate composed of a substrate main body and two cantilever beam portions, a drive source, a mirror portion, and a supporting component for fixing the substrate main body at a fixed end; and reducing an area of the substrate which protrudes from the fixed end to an outside of the supporting component, thereby to increase the resonance frequency; or alternatively, increasing the area of the substrate which protrudes from the fixed end to the outside of the supporting component, thereby to reduce the resonance frequency.

Abstract: An optical scanning device of the invention includes: a substrate main body; two cantilever beam portions which protrude from both-side portions of one side of the substrate main body; a mirror portion whose both-sides are supported by torsion bar portions between the cantilever beam portions; a drive source which causes the substrate main body to oscillate; and a light source which projects light onto the mirror portion, where the mirror portion resonates and vibrates in accordance with a vibration imparted to a substrate by the drive source, and a direction of reflection light from the light projected onto the mirror portion from the light source changes in accordance with the vibration of the mirror portion, and where a fixed end portion of the substrate main body which is located on the opposite side thereof from the mirror portion side is fixed to a supporting component, and the drive source is provided on a portion of the substrate main body.

Abstract: [Problem] A flow rate measuring device in which guided waves are used, wherein the frequency of ultrasound is optimized; and energy injected from ultrasound transmission/reception elements is increased and the flow velocity sensitivity is raised; whereby the measurement accuracy is improved. [Solution] A frequency of an isolated peak of group velocities of guided waves, from among a plurality of peaks of group velocities of guided waves, and a resonance frequency of the ultrasound transmission element/reception element are set to agree; and the semi-amplitude of a power spectrum of ultrasound excited/received by the ultrasound transmission element/reception element is set to a value that does not overlap with another peak of group velocities.

Abstract: A semiconductor device includes a semiconductor chip having a surface provided with connecting electrodes, a stacked structure made up of alternately stacked dielectric and wiring layers and provided on the surface of the semiconductor chip, a passive element provided in the stacked structure and electrically connected to the wiring layers; and external electrodes for external electrical connection provided on the stacked structure and electrically connected to the connecting electrodes via the wiring layers. The passive element has at least one layer selected from a group consisting of a capacitor dielectric layer, a resistor layer and a conductor layer that are formed by spraying an aerosol particulate material.

Abstract: An optical scanning device, having: a substrate main body; two cantilever beams protruded from the respective side portion of one side of the substrate main body; a mirror supported by torsion bars from the respective side, between the cantilever beams; a drive source to causes the substrate main body to vibrate; and a light source to project light onto the mirror, wherein a fixed end of the substrate main body is fixed to a supporting member, on the opposite side from the mirror side, and wherein the mirror resonantly vibrates according to vibration applied to the substrate by the drive source, thereby to change a direction of reflection light of the light projected onto the mirror from the light source according to the vibration of the mirror, characterized in that a Si mirror is attached to and fixed on the mirror.

Abstract: An optical scanning device of the invention includes: a substrate; a torsion bar portion which is connected to the substrate; a mirror portion which is supported by the torsion bar portion; a drive source which causes the substrate to oscillate; and a light source which projects light onto the mirror portion, where the mirror portion resonates and vibrates in accordance with a vibration imparted to the substrate by the drive source, a direction of reflection light from the light projected onto the mirror portion from the light source changes in accordance with the vibration of the mirror portion, the drive source is provided on a portion of the substrate at a distance from a connected portion where the substrate is connected to the torsion bar portion, and a substrate shape control device which controls the shape of the substrate itself is provided on the substrate.

Abstract: An optical scanning device, having: a substrate main body; two cantilever beams protruded from the respective side portion of one side of the main body; a mirror supported by torsion bars from the respective side, between the beams; a drive source to causes the main body to vibrate; and a light source to project light onto the mirror, wherein a fixed end of the main body is fixed to a supporting member, on the opposite side from the mirror side, wherein the drive source is provided on a part of the main body, and wherein the mirror resonantly vibrates according to vibration applied to the substrate by the drive source, thereby to change a direction of reflection light of the light projected onto the mirror according to the vibration of the mirror, characterized in that a plurality of holes are provided in the main body and the beams.

Abstract: A composite structure forming method comprises the steps of first pre-treating brittle material fine particles to impart an internal strain to the brittle material fine particles, secondly causing the brittle material fine particles in which the internal strain has been created to collide with a substrate surface at high speed or applying a mechanical impact force to the brittle material fine particles containing the internal strain therein provided on the substrate surface, to deform or fracture the brittle material fine particles, re-joining the fine particles through active new surfaces generated by the deformation or fracture, forming an anchor section made of polycrystalline brittle material of which part bites into the substrate surface at a boundary section between the new surfaces and the substrate, and further forming a structure made of polycrystalline brittle material on the anchor section.

Abstract: A simple method is provided for manufacturing a film such as a piezoelectric film wherein the adhesiveness of the film on a substrate can be improved. An aerosol containing particles is ejected onto a substrate so that the particles adhere thereto, wherein the ratio between the Vickers hardness Hv(b) of the adhesion surface to which the particles are attached in the substrate, and the Vickers hardness Hv(p) of the particles is within a range of 0.39?Hv(p)/Hv(b)?3.08. The adhesiveness between the particles and the substrate can thereby be improved to reliably form a film. The present invention can be satisfactorily applied to the formation of a piezoelectric film.

Abstract: A film forming apparatus includes a film forming chamber for performing a film formation; an exhaust unit connected to the film forming chamber to discharge a gas out of the film forming chamber; a holder provided in the film forming chamber to hold a process-objective material; a jetting nozzle provided in the film forming chamber on which a jetting port is formed in a slit shape, and jetting an aerosol containing particulate material to form a film made of the particulate material on the process-objective material; and a shielding member provided at a side of the jetting port in a longitudinal direction of the jetting port to cover a side of a jet flow of the aerosol jetted from the jetting port. Accordingly, it is possible to suppress a turbulence of a flow of the aerosol due to an exhaust flow, and to form the film uniformly.

Abstract: In a compact formed by subjecting an ultrafine particle brittle material supplied on a substrate to mechanical impact force as a load, whereby the ultrafine particle brittle material is crushed and joined to each other, manganese is added into the ultrafine particle brittle material to form the compact.

Abstract: A film forming apparatus including a film forming chamber which forms a film, a jetting mechanism which jets aerosol containing material particles onto a substrate in the film forming chamber, a measuring chamber communicating with the film forming chamber, a measuring mechanism which measures a thickness of the film in the measuring chamber, a pressure adjusting mechanism which controls an internal pressure of the film forming chamber and the measuring chamber, a conveyor which transports the substrate between the film forming chamber and the measuring chamber, and a blocking section which blocks a communication between the film forming chamber and the measuring chamber. Accordingly, inside of the measuring chamber is maintained clean without being polluted with the aerosol, and the measurement precision can be maintained. In the film forming process, the film thickness can be easily and precisely measured, and fed back to the film forming condition.

Abstract: A film forming apparatus includes an aerosol generating section which generates an aerosol; a jetting nozzle having an internal passage formed therein and through which the aerosol flows, the internal passage having one end serving as a supply port of the aerosol and having other end serving as a jetting port of the aerosol; a narrowed channel which is provided in the internal passage and which has a channel area narrower than a channel area on an upstream of the narrowed channel; and a collision portion which is provided in the internal passage on a downstream of the narrowed channel, and against which a flow of the aerosol passed through the narrowed channel collides. Since the aggregated particles are crushed and supplied from the jetting nozzle in the form of fine particles, a thin and uniform film can be formed on the process-objective material.

Abstract: A method of adjusting a resonance frequency in an optical scanning device, containing: providing the optical scanning device, having: a substrate composed of a substrate main body and two cantilever beam portions; a drive source; a mirror portion; and a supporting component for fixing the substrate main body at a fixed end; and reducing an area of the substrate which protrudes from the fixed end to an outside of the supporting component, thereby to increase the resonance frequency; or alternatively, increasing the area of the substrate which protrudes from the fixed end to the outside of the supporting component, thereby to reduce the resonance frequency.

Abstract: Disclosed herein is a fine and thick wiring drawn at high speed in such a manner that a region on the substrate, on which region the liquid droplet is scheduled to impact, is heated beforehand, and that immediately after the impact of the liquid droplet on the substrate, the liquid droplet is promptly solidified so as thereby to suppress the spread of the liquid droplet due to the wettability of the liquid droplet to the substrate, and also to suppress the clogging of the nozzle due to the heating of the substrate. Thereby, even in the case where a liquid droplet having a larger volume than before is used, high-speed drawing of a thick and fine wiring having a line width approximately equal to the liquid droplet size is realized independently of the substrate material.

Abstract: A method of producing a piezoelectric actuator includes the steps of: forming a first electrode layer on a substrate by jetting an aerosol containing particles of a conductive material and ceramic particles onto the substrate to make the particles adhere to the substrate; forming a piezoelectric layer on the first electrode layer by jetting an aerosol containing particles of a piezoelectric material onto the first electrode layer to make the particles adhere to the electrode; performing an annealing treatment for the piezoelectric layer; and forming, on the piezoelectric layer, a second electrode layer paring with the first electrode layer. Accordingly, the adherence between the substrate and the first electrode layer and between the first electrode layer and the piezoelectric layer are improved, thereby hardly causing exfoliation of the layers due to differences in coefficients of thermal expansion between the layers.

Abstract: A composite structure forming method comprises the steps of first pre-treating brittle material fine particles to impart an internal strain to the brittle material fine particles, secondly causing the brittle material fine particles in which the internal strain has been created to collide with a substrate surface at high speed or applying a mechanical impact force to the brittle material fine particles containing the internal strain therein provided on the substrate surface, to deform or fracture the brittle material fine particles, re-joining the fine particles through active new surfaces generated by the deformation or fracture, forming an anchor section made of polycrystalline brittle material of which part bites into the substrate surface at a boundary section between the new surfaces and the substrate, and further forming a structure made of polycrystalline brittle material on the anchor section.

Abstract: A composite structure forming method comprises the steps of first pre-treating brittle material fine particles to impart an internal strain to the brittle material fine particles, secondly causing the brittle material fine particles in which the internal strain has been created to collide with a substrate surface at high speed or applying a mechanical impact force to the brittle material fine particles containing the internal strain therein provided on the substrate surface, to deform or fracture the brittle material fine particles, re-joining the fine particles through active new surfaces generated by the deformation or fracture, forming an anchor section made of polycrystalline brittle material of which part bites into the substrate surface at a boundary section between the new surfaces and the substrate, and further forming a structure made of polycrystalline brittle material on the anchor section.

Abstract: An optical scanning device of the invention includes: a substrate; torsion bar portion which is connected to the substrate; a mirror portion which is supported by the torsion bar portion; a drive source which causes the substrate to oscillate; and a light source which projects light onto the mirror portion, where the mirror portion resonates and vibrates in accordance with a vibration imparted to the substrate by the drive source, and the direction of reflection light from the light projected onto the mirror portion from the light source changes in accordance with the vibration of the mirror portion, and a spring constant in a longitudinal direction of the torsion bar portion supporting the mirror portion is distributed along the longitudinal direction of the torsion bar portion.