Your search keyword '"Hirahara, M."' showing total 5 results

1. Next-Generation Plasma Particle Measurements in the Medium Energy Range: Development of Cusp Type Electrostatic Analyser and Ion Mass Spectrometer.

Author

Kasahara, S., Asamura, K., Takashima, T., Hirahara, M., Ogasawara, K., and Saito, Y.

Subjects

ELECTROSTATIC analyzers, PARTICLES (Nuclear physics), MASS spectrometers, PLASMA gases, SPECTROMETERS

Abstract

In regions such as the reconnection sites and the ring current, plasmas are highly accelerated and their energies sometimes exceed the uppermost energy level of low-energy plasma sensors (typically ∼40 keV). In order to study acceleration mechanisms in such key regions, in-situ observations with continuous energy coverage from low (∼ eV) to medium (∼10–∼200 keV) or to even higher energies are necessary. In fact, ERG and Cross scale missions are planned to explore the above regions with plasma instrument packages that require covering the majority of the energy range. We, therefore, develop a medium energy ion mass spectrometer, which consists of an Electrostatic Analyser (ESA), a Time-of-Flight mass spectrometer (ToF), and solid-state detectors (SSDs). It can simultaneously and independently measure energy-per-charge (E/q), velocity (v), and energy (E) of incoming ions, thus deducing E, m, and q. In addition, the coincidence method via the combination of ToF start-stop signals and SSD signals is useful to reject background noise that is caused by radiation belt electrons and/or solar energetic protons. In order to enable electrostatic analyses with a practical sensor size, we have developed a novel “cusp type” electrostatic analyser. This design provides us a relatively small instrument that has an energy range up to ∼200 keV/q with a full solid angle coverage (using the spacecraft spin motion). This kind of electrostatic analyser may also be used for electron measurements. [ABSTRACT FROM AUTHOR]

Published

2009

2. ARGO Science Mission.

Author

Cheng, C. Z., Chen, A., Hau, L. N., Hirahara, M., Lin, C. H., and Yau, A. W.

Subjects

ARTIFICIAL satellites, ELECTROMAGNETIC waves, SPECTROMETERS, PARTICLES (Nuclear physics)

Abstract

Taiwan’s National Space Organization (NSPO) plans to launch a series of scientific satellites during the next 15 years and will actively pursue international collaboration on scientific satellite missions. The next NSPO satellite mission is based on a LEO satellite concept, ARGO, which has a sun-synchronous orbit of 97.9 degree inclination and ∼620 km altitude, and is planned for launch in 2011. Besides carrying a remote sensing camera for earth observation, ARGO will have four space science instruments to carry out the science mission of studying ionospheric physics related to space weather with emphasis on magnetosphere-ionosphere- thermosphere coupling physics, space weather monitoring, and particle and electromagnetic wave phenomena. These four instruments are: a flux gate magnetometer (MFI), an Auroral Electron Spectrometer (AES) with energy coverage from ∼12 eV to ∼18 keV, an Imaging and Rapid-scanning ion Mass spectrometer (IRM) with energy coverage from ∼0.5 to ∼70 eV, and an Atmospheric Neutral Analyzer (ANA) which covers 0.1–2 km/s neutral velocity range. These instruments will have high time resolution and good pitch angle coverage. The science instrument operation will be open for coordinated observation campaigns with other satellite missions (FORMOSAT-2, Reimei, THEMIS, Cassiope, QuickSat, etc.) and ground-based observations. [ABSTRACT FROM AUTHOR]

Published

2009

3. Ground-based observations of diffuse auroral structures in conjunction with Reimei measurements.

Author

Samara, M., Michell, R. G., Asamura, K., Hirahara, M., Hampton, D. L., and H. C. Stenbaek-Nielsen

Subjects

AURORAS, IONOSPHERE, ELECTRON precipitation, ARTIFICIAL satellites, PARTICLES (Nuclear physics), UNSTEADY flow

Abstract

We present results from ground-based auroral observations coordinated with the Japanese satellite, Reimei, that took place during the winters of 2006, 2007 and 2008 at Poker Flat, Alaska. Comparable temporal and spatial resolution for the optical and in situ particle data, allowed for investigation of small scale and/or rapidly time-varying auroral structures. Four satellite passes through diffuse auroral structures were identified. The structures within the aurora, whether stationary or time-varying (pulsating aurora), were most closely correlated with the highest energy precipitating electrons measured by these detectors (8 to 12 keV). This relation is found to be consistent across all four examples, revealing that the electron precipitation responsible for these diffuse auroral structures is primarily that of the ⩾8 keV electrons. [ABSTRACT FROM AUTHOR]

Published

2010

4. Cusp type electrostatic analyzer for measurements of medium energy charged particles.

Author

Kasahara, S., Asamura, K., Saito, Y., Takashima, T., Hirahara, M., and Mukai, T.

Subjects

ELECTROSTATIC analyzers, PHYSICS instruments, FORCE & energy, PARTICLES (Nuclear physics), MEASUREMENT, SIMULATION methods & models, METHODOLOGY, MAGNETOSPHERE

Abstract

We have developed a new electrostatic analyzer which enables medium energy (<=200 keV/q) plasma particle measurements with full solid angle coverage. The design of the test model realizes the uppermost measurement energy of ∼200 keV/q with applied high voltages of ±5 kV. Laboratory experiments with the test model analyzer show that its performance agrees with numerical simulations. The test model design is well suited for combination with a mass analysis unit, while our new design can also be applied to medium energy electron measurements. Medium energy ion/electron sensors with this new design will surely be appreciated for upcoming space missions that will observe hot/energetic plasma structures in the regions such as the inner magnetosphere or reconnection region. [ABSTRACT FROM AUTHOR]

Published

2006

5. Scientific objectives and instrumentation of Mercury Plasma Particle Experiment (MPPE) onboard MMO

Author

Saito, Y., Sauvaud, J.A., Hirahara, M., Barabash, S., Delcourt, D., Takashima, T., and Asamura, K.

Subjects

*PLANETARY magnetospheres, *SPACE plasmas, *PARTICLES (Nuclear physics), *MASS spectrometers, *SPACE flight to Mercury, *PLANETARY observations, *EXPLORATION of Mercury, *MERCURIAN atmosphere, *MERCURY (Planet)

Abstract

Abstract: Mercury is one of the least explored planets in our solar system. Until the recent flyby of Mercury by MESSENGER, no spacecraft had visited Mercury since Mariner 10 made three flybys: two in 1974 and one in 1975. In order to elucidate the detailed plasma structure and dynamics around Mercury, an orbiter BepiColombo MMO (Mercury Magnetospheric Orbiter) is planned to be launched in 2013 as a joint mission between ESA and ISAS/JAXA. Mercury Plasma Particle Experiment (MPPE) was proposed in order to investigate the plasma/particle environment around Mercury. MPPE is a comprehensive instrument package for plasma, high-energy particle and energetic neutral atom measurements. It consists of seven sensors: two Mercury electron analyzers (MEA1 and MEA2), Mercury ion analyzer (MIA), Mercury mass spectrum analyzer (MSA), high-energy particle instrument for electron (HEP-ele), high-energy particle instrument for ion (HEP-ion), and energetic neutrals analyzer (ENA). Since comprehensive full three-dimensional simultaneous measurements of low to high-energy ions and electrons around Mercury as well as measurements of energetic neutral atoms will not be realized before BepiColombo/MMO''s arrival at Mercury, it is expected that many unresolved problems concerning the Mercury magnetosphere will be elucidated by the MPPE observation. [Copyright &y& Elsevier]

Published

2010