Abstract: [Problem] To provide a metabolic syndrome inhibitor which can inhibit the accumulation of visceral fat and body fat to thereby ameliorate or prevent metabolic syndrome. [Solution] The metabolic syndrome inhibitor according to the present invention comprises soybean hypocotyl oil as an active ingredient. In particular, the metabolic syndrome inhibitor serves as a body fat accumulation inhibitor and/or a blood neutral fat increase inhibitor. In particular, the body fat accumulation inhibitor serves as a visceral fat accumulation inhibitor.

Abstract: A method is provided to promote secretion of cholecystokinin (CCK) by administering an active component. The active component includes acrylic acid and/or an unsaturated aldehyde having a main chain of 4 to 12 carbon atoms having a double bond in at least position 2 or 4, where the main chain has 4 to 9 carbon atoms when there is a double bond in only position 2, and the main chain has 9 to 12 carbon atoms when there is a double bond in only position 4. The cholecystokinin secretion-promoting composition can be used as an appetite suppressant. By adding this cholecystokinin secretion-promoting composition to food, appetite-suppressing food products can be provided.

Abstract: A method is provided to promote secretion of cholecystokinin (CCK) by administering an active component. The active component includes acrylic acid and/or an unsaturated aldehyde having a main chain of 4 to 12 carbon atoms having a double bond in at least position 2 or 4, where the main chain has 4 to 9 carbon atoms when there is a double bond in only position 2, and the main chain has 9 to 12 carbon atoms when there is a double bond in only position 4. The cholecystokinin secretion-promoting composition can be used as an appetite suppressant. By adding this cholecystokinin secretion-promoting composition to food, appetite-suppressing food products can be provided.

Abstract: A CCK secretion-promoting substance and a use thereof are provided. This cholecystokinin secretion-promoting composition contains, as an active component, acrylic acid and/or an unsaturated aldehyde having a main chain of 4-12 carbon atoms having a double bond in at least position 2 or 4, wherein the main chain has 4-9 carbon atoms if there is a double bond only in position 2 and the main chain has 9-12 carbon atoms if there is a double bond only in position 4. This cholecystokinin secretion-promoting composition can be used as an appetite suppressant. By adding this cholecystokinin secretion-promoting composition to food, appetite-suppressing food products can be provided.

Abstract: A repeller structure is provided in a plasma generating chamber of an ion source facing a cathode that emits electrons for ionizing a source gas in the plasma generating chamber to generate a plasma. The repeller structure reflects the ions toward the cathode. The repeller structure includes a sputtering target that is sputtered by the plasma to emit predetermined ions, the sputtering target including a through hole that connects a sputtering surface and a back surface of the sputtering target; and an electrode body that is inserted in the through hole, the electrode body including a repeller surface that is exposed to the sputtering surface side through the through hole.

Abstract: An ion implanting apparatus includes: an electrostatic accelerating tube for causing an ion beam extracted from an ion source to have a desirable energy, and deflecting the ion beam to be incident on a target, the electrostatic accelerating tube including deflecting electrodes provided to interpose the ion beam therebetween. The deflecting electrodes include a first deflecting electrode and a second deflecting electrode to which different electric potentials from each other are set. The second deflecting electrode is provided on a side where the ion beam is to be deflected and includes an upstream electrode provided on an upstream side of the ion beam and a downstream electrode provided apart from the upstream electrode toward a downstream side. An electric potential of the upstream electrode and an electric potential of the downstream electrode are independently set from each other.

Abstract: An ion source includes a plasma generating chamber into which an ionization gas containing fluorine is introduced, a hot cathode provided on one side in the plasma generating chamber, an opposing reflecting electrode which is provided on other side in the plasma generating chamber and reflects electrons when a negative voltage is applied from a bias power supply to the opposing reflecting electrode, and a magnet for generating a magnetic field along a line, which connects the hot cathode and the opposing reflecting electrode, in the plasma generating chamber. The opposing reflecting electrode is formed of an aluminum containing material.

Abstract: An ion implanting apparatus includes: an electrostatic accelerating tube for causing an ion beam extracted from an ion source to have a desirable energy, and deflecting the ion beam to be incident on a target, the electrostatic accelerating tube including deflecting electrodes provided to interpose the ion beam therebetween. The deflecting electrodes include a first deflecting electrode and a second deflecting electrode to which different electric potentials from each other are set. The second deflecting electrode is provided on a side where the ion beam is to be deflected and includes an upstream electrode provided on an upstream side of the ion beam and a downstream electrode provided apart from the upstream electrode toward a downstream side. An electric potential of the upstream electrode and an electric potential of the downstream electrode are independently set from each other.

Abstract: There is provided a fat composition that makes possible to prepare stir-fried food, deep-fried food or mayonnaise. The fat composition contains an emulsifier having an HLB of not more than 5 in an amount of 0.1 to 3% by weight.

Abstract: To increase a transport efficiency of an ion beam by correcting Y-direction diffusion caused by the space charge effect of the ion beam between an ion beam deflector, which separates the ion beam and neutrons from each other, and a target. An ion implantation apparatus has a beam paralleling device that bends an ion beam scanned in an X direction by magnetic field to be parallel and draws a ribbon-shaped ion beam. The beam paralleling device serves also as an ion beam deflector that deflects the ion beam by magnetic field to separates neutrons from the ion beam. In the vicinity of an outlet of the beam paralleling device, there is provided an electric field lens having a plurality of electrodes opposed to each other in a Y direction with a space for passing the ion beam and narrowing the ion beam in the Y direction.

Abstract: A repeller structure is provided in a plasma generating chamber of an ion source facing a cathode that emits electrons for ionizing a source gas in the plasma generating chamber to generate a plasma. The repeller structure reflects the ions toward the cathode. The repeller structure includes a sputtering target that is sputtered by the plasma to emit predetermined ions, the sputtering target including a through hole that connects a sputtering surface and a back surface of the sputtering target; and an electrode body that is inserted in the through hole, the electrode body including a repeller surface that is exposed to the sputtering surface side through the through hole.

Abstract: This ion source generates a ribbon-like ion beam whose dimension in the Y direction is larger than the dimension in the X direction. This ion source includes a plasma generating vessel having an ion extraction port extending in the Y direction, a plurality of cathodes arranged in a plurality of stages along the Y direction on one side in the X direction in the plasma generating vessel, a reflecting electrode arranged on the other side in the X direction in the plasma generating vessel opposite to the cathodes, and electromagnets for generating magnetic fields along the X direction in regions including the plurality of cathodes in the plasma generating vessel.

Abstract: An extraction electrode of an ion source is dividedly configured by a first extraction electrode and a second extraction electrode. DC power supplies which form a potential difference between the electrodes, a camera which takes an image of the ion beam to output image data of the ion beam, and a rear-stage beam instrument which measures the beam current of the ion beam that has passed through the analysis slit are disposed.

Abstract: An ion source is to extract a ribbon-shaped ion beam longer in the Y direction in the Z direction and provided with a plasma generating chamber, a plasma electrode which is disposed near the end of the plasma generating chamber in the Z direction and has an ion extracting port extending in the Y direction, a plurality of cathodes for emitting electrons into the plasma generating chamber to generate a plasma and arranged in a plurality of stages along the Y direction, and a magnetic coil which generates magnetic fields along the Z direction in a domain containing the plurality of cathodes inside the plasma generating chamber.

Abstract: An ion source is provided that can generate an ion beam in which the width is wide, the beam current is large, and the uniformity of the beam current distribution in the width direction is high, and that can prolong the lifetime of a cathode. The ion source 2a has: a plasma generating chamber 6 having an ion extraction port 8 extending in the X direction; a magnet 14 which generates a magnetic field 16 extending along the X direction, in the plasma generating chamber 6; indirectly-heated cathodes 20 which are placed respectively on the both sides of the plasma generating chamber 6 in the X direction, and which are used for generating a plasma i0 in the chamber 6, and increasing or decreasing the density of the whole of the plasma 10; and plural filament cathodes 32 which are juxtaposed in the X direction in the plasma generating chamber 6, and which are used for generating the plasma i0 in the chamber 6, and controlling the density distribution of the plasma 10.

Abstract: An ion source includes a plasma generating chamber into which an ionization gas containing fluorine is introduced, a hot cathode provided on one side in the plasma generating chamber, an opposing reflecting electrode which is provided on other side in the plasma generating chamber and reflects electrons when a negative voltage is applied from a bias power supply to the opposing reflecting electrode, and a magnet for generating a magnetic field along a line, which connects the hot cathode and the opposing reflecting electrode, in the plasma generating chamber. The opposing reflecting electrode is formed of an aluminum containing material.

Abstract: An analyzing electromagnet constituting an ion implanter has a first inner coil, a second inner coil, three first outer coils, three second outer coils, and a yoke. The inner coils are saddle-shaped coils cooperating with each other to generate a main magnetic field which bends an ion beam in the X direction. Each of the outer coils is a saddle-shaped coil which generates a sub-magnetic field correcting the main magnetic field. Each of the coils has a configuration where a notched portion is disposed in a fan-shaped cylindrical stacked coil configured by: winding a laminations of an insulation sheet and a conductor sheet in multiple turn on an outer peripheral face of a laminated insulator; and forming a laminated insulator on an outer peripheral face.

Abstract: An extraction electrode of an ion source is dividedly configured by a first extraction electrode and a second extraction electrode. DC power supplies which form a potential difference between the electrodes, a camera which takes an image of the ion beam to output image data of the ion beam, and a rear-stage beam instrument which measures the beam current of the ion beam that has passed through the analysis slit are disposed.

Abstract: To increase a transport efficiency of an ion beam by correcting Y-direction diffusion caused by the space charge effect of the ion beam between an ion beam deflector, which separates the ion beam and neutrons from each other, and a target. An ion implantation apparatus has a beam paralleling device that bends an ion beam scanned in an X direction by magnetic field to be parallel and draws a ribbon-shaped ion beam. The beam paralleling device serves also as an ion beam deflector that deflects the ion beam by magnetic field to separates neutrons from the ion beam. In the vicinity of an outlet of the beam paralleling device, there is provided an electric field lens having a plurality of electrodes opposed to each other in a Y direction with a space for passing the ion beam and narrowing the ion beam in the Y direction.

Abstract: The ion implanter has: an ion source which generates an ion beam; electron beam sources which emit an electron beam to be scanned in the Y direction in the ion source; a power source for the sources; an ion beam monitor which, in the vicinity of an implanting position, measures a Y-direction ion beam current density distribution of the ion beam; and a controlling device. The controlling device has a function of homogenizing the Y-direction ion beam current density distribution measured by the monitor, by, while controlling the power sources on the basis of measurement data of the monitor, increasing a scanning speed of the electron beam in a position corresponding to a monitor point where an ion beam current density measured by the monitor is large; and decreasing the scanning speed of the electron beam in a position corresponding to a monitor point where the measured ion beam current density is small.