Abstract: An analysis method includes: obtaining n×m pieces of map data by repeating, m times, a map measurement in which n pieces of map data are obtained by scanning a specimen with a primary probe to detect electrons emitted from the specimen with an electron spectrometer, while measurement energy ranges of an analyzer are varied; and generating a spectral map in which a position on the specimen is associated with a spectrum based on the n×m pieces of map data, the measurement energy ranges of m times of the map measurement not overlapping each other.

Abstract: An input lens is provided which has a large acceptance solid angle for electrons. The input lens is for use in an electron spectrometer and disposed between an electron source producing electrons and an electron analyzer in the electron spectrometer. The input lens has a reference electrode at a reference potential, a slit, first through nth electrodes, where n is an integer equal to or greater than three, arranged between the reference electrode and the slit, and a second mesh attached to the first electrode. The first through nth electrodes are arranged in this order along an optical axis. The second mesh is at a potential higher than the reference potential.

Abstract: A charged particle beam device includes: a charged particle beam source; an analyzer that analyzes and detects particles including secondary electrons and backscattered charged particles that are emitted from a specimen by irradiating the specimen with a primary charged particle beam emitted from the charged particle beam source; a bias voltage applying unit that applies a bias voltage to the specimen; and an analysis unit that extracts a signal component of the secondary electrons based on a first spectrum obtained by detecting the particles with the analyzer in a state where a first bias voltage is applied to the specimen, and a second spectrum obtained by detecting the particles with the analyzer in a state where a second bias voltage different from the first bias voltage is applied to the specimen.

Abstract: A thermally conductive elastomer composition of the present technology contains 100 parts by mass of a styrene-based elastomer, from 400 to 540 parts by mass of a process oil formed of a petroleum-based hydrocarbon, from 950 to 1350 parts by mass of aluminum hydroxide having an average particle diameter from 3 ?m to 20 ?, and from 70 to 80 parts by mass of expanded graphite having an average particle diameter from 3 ?m to 20 ?m, where a difference between the average particle diameter of the aluminum hydroxide and the average particle diameter of the expanded graphite is within 5 ?m.

Abstract: A fixture according to an aspect of the present disclosure includes a shaft portion, a first fixing portion, a spacer, and a second fixing portion. A connection portion passing through the inside of the spacer and being connected to both the shaft portion and the second fixing portion is provided inside the spacer. The shaft portion includes a first hard resin portion, a second hard resin portion, and a soft resin portion. A soft resin portion is interposed between the first hard resin portion and the second hard resin portion so that vibration transmitted from either the first hard resin portion or the second hard resin portion to the other can be dampened.

Abstract: Provided is a thermally conductive elastomer composition excellent in thermal conductivity, insulation property, low hardness property, moldability, and the like. [Solving Means] The thermally conductive elastomer composition of the present invention including: a styrene-based elastomer in an amount of 100 parts by mass; a process oil in an amount of 800 to 1,000 parts by mass including a petroleum-based hydrocarbon; an aluminum hydroxide powder in an amount of 240 to 290 parts by mass; and an artificial graphite powder in a platelike form with an average particle size of 8 ?m to 30 ?m, or a natural graphite powder in a flake form or a vein form with an average particle size of 8 ?m to 30 ?m, in an amount of 270 to 400 parts by mass.

Abstract: A method of generating an elemental map includes: acquiring a plurality of correction channel images by scanning a surface of a standard specimen having a uniform elemental concentration with a primary beam and generating a correction channel image for each channel; generating correction information for each pixel of each correction channel image among the plurality of correction channel images based on a brightness value of the pixel; acquiring a plurality of analysis channel images by scanning a surface of a specimen to be analyzed with the primary beam and generating an analysis channel image for each channel; correcting brightness values of pixels constituting an analysis channel image among the plurality of analysis channel images based on the correction information; and generating an elemental map of the specimen to be analyzed based on the plurality of analysis channel images having pixels with corrected brightness values.

Abstract: Provided is a thermally conductive elastomer composition excellent in thermal conductivity, insulation property, low hardness property, moldability, and the like. [Solving Means] The thermally conductive elastomer composition of the present invention including: a styrene-based elastomer in an amount of 100 parts by mass; a process oil in an amount of 800 to 1,000 parts by mass including a petroleum-based hydrocarbon; an aluminum hydroxide powder in an amount of 240 to 290 parts by mass; and an artificial graphite powder in a platelike form with an average particle size of 8 ?m to 30 ?m, or a natural graphite powder in a flake form or a vein form with an average particle size of 8 ?m to 30 ?m, in an amount of 270 to 400 parts by mass.

Abstract: A fixture according to an aspect of the present disclosure includes a shaft portion, a first fixing portion, a spacer, and a second fixing portion. A connection portion passing through the inside of the spacer and being connected to both the shaft portion and the second fixing portion is provided inside the spacer. The shaft portion includes a first hard resin portion, a second hard resin portion, and a soft resin portion. A soft resin portion is interposed between the first hard resin portion and the second hard resin portion so that vibration transmitted from either the first hard resin portion or the second hard resin portion to the other can be dampened.

Abstract: A hybrid vehicle control device includes an engine, a motor/generator, an automatic transmission in which the gear ratio can be fixed by the driver's intention; and a drive wheel. The control device has an assist traveling mode and an engine generation traveling mode as hybrid modes in which the engine and the motor/generator are drive sources. The control device includes a rotational speed limit setting unit which sets a value that exceeds the upper rotational speed limit, at which the motor/generator can carry out a torque output, as the rotational speed limit of the engine motor rotational speed, and a rotational speed limit control unit for reducing the rotational speed limit to the rotational speed limit at which the motor/generator can carry out a torque output, when the engine motor rotational speed has reached the rotational speed limit and there is a torque output request of the motor/generator.

Abstract: A hybrid vehicle control device includes an engine, a motor/generator, an automatic transmission in which the gear ratio can be fixed by the driver's intention; and a drive wheel. The control device has an assist traveling mode and an engine generation traveling mode as hybrid modes in which the engine and the motor/generator are drive sources. The control device includes a rotational speed limit setting unit which sets a value that exceeds the upper rotational speed limit, at which the motor/generator can carry out a torque output, as the rotational speed limit of the engine motor rotational speed, and a rotational speed limit control unit for reducing the rotational speed limit to the rotational speed limit at which the motor/generator can carry out a torque output, when the engine motor rotational speed has reached the rotational speed limit and there is a torque output request of the motor/generator.

Abstract: In a nanochannel thin film in which oxide layers have surfactant micelles therein, the presence of a target substance in a sample solution is detected with a luminescence intensity of a thin film provided by recognition of the target substance with a luminescent recognition reagent in the nanochannels. Upon focusing on a hydrophobic field provided by the presence of the surfactant in pores of a nanometer size, the novel development of a sensor function is enabled.

Abstract: This invention provides a method for producing an optically active aziridine compound or amine compound, which uses as a catalyst a Ru(salen)(CO) complex represented by the following formula (I) or its enantiomer having a high stability, in a high turnover number (TON) and a high enantioselectivity. In the formula (I), Ar is represented by the following formula (VI) or (VII), wherein in the formula (VI), Xs are independently a halogen or a halogenated alkyl group and R1 and R2s are independently hydrogen or an alkyl group or a trialkylsilyl group having a carbon number of 1-4, and in the formula (VII), R3 is a bulky group.

Abstract: This invention provides a method for producing an optically active aziridine compound or amine compound, which uses as a catalyst a Ru(salen)(CO) complex represented by the following formula (I) or its enantiomer having a high stability, in a high turnover number (TON) and a high enantioselectivity. In the formula (I), Ar is represented by the following formula (VI) or (VII), wherein in the formula (VI), Xs are independently a halogen or a halogenated alkyl group and R1 and R2s are independently hydrogen or an alkyl group or a trialkylsilyl group having a carbon number of 1-4, and in the formula (VII), R3 is a bulky group.

Abstract: This invention provides a method for producing an optically active aziridine compound or amine compound, which uses as a catalyst a Ru(salen)(CO) complex represented by the following formula (I) or its enantiomer having a high stability, in a high turnover number (TON) and a high enantioselectivity. In the formula (I), Ar is represented by the following formula (VI) or (VII), wherein in the formula (VI), Xs are independently a halogen or a halogenated alkyl group and R1 and R2s are independently hydrogen or an alkyl group or a trialkylsilyl group having a carbon number of 1-4, and in the formula (VII), R3 is a bulky group.

Abstract: This invention provides a method for producing an optically active aziridine compound or amine compound, which uses as a catalyst a Ru(salen)(CO) complex represented by the following formula (I) or its enantiomer having a high stability, in a high turnover number (TON) and a high enantioselectivity. In the formula (I), Ar is represented by the following formula (VI) or (VII), wherein in the formula (VI), Xs are independently a halogen or a halogenated alkyl group and R1 and R2s are independently hydrogen or an alkyl group or a trialkylsilyl group having a carbon number of 1-4, and in the formula (VII), R3 is a bulky group.

Abstract: This invention provides a method for producing an optically active aziridine compound or amine compound, which uses as a catalyst a Ru(salen)(CO) complex represented by the following formula (I) or its enantiomer having a high stability, in a high turnover number (TON) and a high enantioselectivity. In the formula (I), Ar is represented by the following formula (VI) or (VII), wherein in the formula (VI), Xs are independently a halogen or a halogenated alkyl group and R1 and R2s are independently hydrogen or an alkyl group or a trialkylsilyl group having a carbon number of 1-4, and in the formula (VII), R3 is a bulky group.

Abstract: This invention provides a method for producing an optically active aziridine compound or amine compound, which uses as a catalyst a Ru(salen)(CO) complex represented by the following formula (I) or its enantiomer having a high stability, in a high turnover number (TON) and a high enantioselectivity. In the formula (I), Ar is represented by the following formula (VI) or (VII), wherein in the formula (VI), Xs are independently a halogen or a halogenated alkyl group and R1 and R2s are independently hydrogen or an alkyl group or a trialkylsilyl group having a carbon number of 1-4, and in the formula (VII), R3 is a bulky group.

Abstract: The crystal oscillator nanochannel sensor comprises a nanochannel structure thin film arranged on an electrode surface of a crystal oscillator and having an oxide layer which contains a surfactant micelle. The sensor senses the existence of a target substance in an analyte solution through a weight change in a nanochannel caused by a recognition reagent and the target substance collected by the recognition reagent. The invention provides a new application of crystal oscillator sensors by utilizing a hydrophobic site provided by the surfactant in a nanometer-size pore.

Abstract: In a nanochannel thin film in which oxide layers have surfactant micelles therein, the presence of a target substance in a sample solution is detected with a luminescence intensity of a thin film provided by recognition of the target substance with a luminescent recognition reagent in the nanochannels. Upon focusing on a hydrophobic field provided by the presence of the surfactant in pores of a nanometer size, the novel development of a sensor function is enabled.