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Hinode: A New Solar Observatory in Space H. Hara ( NAOJ/NINS) and the Hinode team 2007 Dec 8
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Japanese Sun Observing Spacecrafts Hinotori (ASTRO-A) Yohkoh (SOLAR-A) Hinode (SOLAR-B) 188 kg Launched in 1981 Feb 390 kg Launched in 1991 Aug 900 kg Launched in 2006 Sep Particle acceleration and plasma heating in solar flares Particle acceleration and plasma heating in solar flares and general coronal activities General solar activities of magnetized plasmas
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SOLAR-B Mission Causal linkages between the photosphere and the upper solar atmosphere, regarding the existence of the chromosphere and corona and their characteristic structures, are investigated. Causal linkages between the photosphere and the upper solar atmosphere, regarding the existence of the chromosphere and corona and their characteristic structures, are investigated. SOLAR-B carries Solar Optical Telescope (SOT), X-ray Telescope (XRT) and EUV Imaging Spectrometer (EIS). SOLAR-B carries Solar Optical Telescope (SOT), X-ray Telescope (XRT) and EUV Imaging Spectrometer (EIS). These three telescopes have been developed in an international collaboration of Japan, US, and UK. These three telescopes have been developed in an international collaboration of Japan, US, and UK. The code name SOLAR-B was renamed to Hinode (sunrise in Japanese) by the late Prof. Kosugi just after the successful launch of the spacecraft on 2006 Sep 23. The code name SOLAR-B was renamed to Hinode (sunrise in Japanese) by the late Prof. Kosugi just after the successful launch of the spacecraft on 2006 Sep 23. 10 m 3.8 m Weight: 900 kg at launch Launch vehicle: M-V-7 th Orbit: Sun-synchronous orbit 680 km altitude
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Telescopes aboard Hinode X-ray Telescope (XRT) Solar Optical Telescope (SOT) EUV Imaging Spectrometer (EIS)
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Solar Atmosphere TR/Corona (EUV) Height from Photosphere (km) SOT EIS Corona XRT Photosphere Chromosphere Corona Transition Region 光球 Temperature (K)
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scientific targets Why the Corona is so Hot? The solar corona is a tenuous 10 6 K magnetized plasma above the photosphere of 6000 K. The solar corona is a tenuous 10 6 K magnetized plasma above the photosphere of 6000 K. Most of stars and cluster of galaxies have the hot corona. Most of stars and cluster of galaxies have the hot corona. A mystery in Astronomy A mystery in Astronomy Detailed studies for understanding the basic reason can be made only for the Sun. Detailed studies for understanding the basic reason can be made only for the Sun. Yohkoh X-ray Image The solar corona over 10 years
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scientific targets Origin of Solar Magnetic Activities Photosphere Chromosphere Corona Temperature minimum Photospheric magnetic field (White/Black: N/S polarity ) The Sun SOT XRT EIS Active phenomena observed in the solar atmosphere are strongly coupled with magnetic fields. Causal linkages between evolution of elementary magnetic fields and the active phenomena are investigated. Size of elementary magnetic fields: 0.2-0.3 arcsec (150-220 km)
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scientific targets Fundamental Process in Space Plasmas - magnetic reconnection - Magnetic reconnection plays an important process to understand solar dynamic events such as solar flares, CME, X-ray jets, and micro- flares. Magnetic reconnection plays an important process to understand solar dynamic events such as solar flares, CME, X-ray jets, and micro- flares. This process is also important to understand the dynamics around star-forming region, stellar flares, and etc. This process is also important to understand the dynamics around star-forming region, stellar flares, and etc. Vector magnetic field measurements with SOT Vector magnetic field measurements with SOT Energy build-up process for solar events becomes a new target. Energy build-up process for solar events becomes a new target. Coronal velocity fields are measured with EIS. Coronal velocity fields are measured with EIS. A Solar flare with Cusp Apex Micro-flares X-ray Jet Plasmoid eruption Plasmoid Flare loop 10 4 km
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Sun-Earth Connection The space environment around the earth, ‘ space weather, ’ is largely affected by the solar activity. The space environment around the earth, ‘ space weather, ’ is largely affected by the solar activity. Deep understanding of flares and CME trigger mechanisms leads to prediction of the space weather conditions. Deep understanding of flares and CME trigger mechanisms leads to prediction of the space weather conditions. Practical aspect of Solar Physics study to Public Practical aspect of Solar Physics study to Public It is expected that Hinode It is expected that Hinode data will contribute to data will contribute to improve the space weather improve the space weather prediction. prediction. Sun Earth
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Solar Optical Telescope (SOT) SOT observes the photosphere and chromosphere in visible-light wavelength (380-670nm) with SOT observes the photosphere and chromosphere in visible-light wavelength (380-670nm) with spatial resolution of 0.2-0.3 arcsec. spatial resolution of 0.2-0.3 arcsec. SOT has SOT has - wide-bandpass (0.5nm) and narrow- bandpass (0.009nm) imagers - wide-bandpass (0.5nm) and narrow- bandpass (0.009nm) imagers - a spectropolarimeter for vector magnetic- field observations. - a spectropolarimeter for vector magnetic- field observations. 0.03 arcsec/10sec stability needed. 0.03 arcsec/10sec stability needed. The telescope has an image stabilization system to achieve this requirement. The telescope has an image stabilization system to achieve this requirement. Correlation tracker + tip-tilt mirror Correlation tracker + tip-tilt mirror OTA FPP The Largest solar telescope ever flown
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SOT: Optical Telescope Assembly (OTA) Side Door Collimater Lens Unit Tip-Tilt Mirror Polarization modulation analyzer Primary Mirror CFRP truss structure Heat Dump Mirror Secondary Mirror Top Door The diffraction-limited solar telescope of 50cm aperture
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SOT: Focal Plane Package (FPP) Filtergraph (FG) Filtergraph (FG) 12 wavelength bandpasses are available. 12 wavelength bandpasses are available. Dynamical motions of magnetized plasmas are observed. Dynamical motions of magnetized plasmas are observed. Spectropolarimeter (SP) Spectropolarimeter (SP) Polarization of Fe I absorption lines at 630 nm is precisely measured. Polarization of Fe I absorption lines at 630 nm is precisely measured. high-resolution vector magnetic fields high-resolution vector magnetic fields Spectropolarimeter (SP) FPP Narrow-bandpass filter Wide-bandpass filters Filtergraph (FG)
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X-Ray Telescope (XRT) The high-resolution Solar X-ray Imager A wide-field (2Kx2K arcsecs) A wide-field (2Kx2K arcsecs) grazing-incidence telescope of grazing-incidence telescope of 2 arcsec resolution 2 arcsec resolution three times better than Yohkoh ’ s Imaging observations of dynamic Imaging observations of dynamic phenomena in the solar corona phenomena in the solar corona High sensitivity for low (1MK) temperature plasmas High sensitivity for low (1MK) temperature plasmas 1 – 30 MK temperature response 1 – 30 MK temperature response On-board flare detection functionality On-board flare detection functionality
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EUV Imaging Spectrometer (EIS) Wavelength ranges: 17-21 nm, 25-20 nm Wavelength ranges: 17-21 nm, 25-20 nm Observation of transition region and corona Observation of transition region and corona 2 arcsec spatial resolution 2 arcsec spatial resolution /4000-5000 spectral resolution/4000-5000 spectral resolution An order of magnitude higher sensitivity than SOHO CDS An order of magnitude higher sensitivity than SOHO CDS Higher cadence observation is possible for dynamic events Higher cadence observation is possible for dynamic events Temperature and density diagnostics from line ratio Temperature and density diagnostics from line ratio The high-sensitivity solar EUV imaging spectrometer
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Key Issues in Spacecraft Selection of sun-synchronous orbit for high pointing stability Selection of sun-synchronous orbit for high pointing stability CFRP optical bench with high heat conduction coefficient for high pointing stability CFRP optical bench with high heat conduction coefficient for high pointing stability Sub-arcsec resolution of sun sensors Sub-arcsec resolution of sun sensors Reduction of micro-vibration Reduction of micro-vibration Low transfer characteristics for mechanical disturbance from attitude sensors and actuators (gyros and momentum wheels) to Optical Telescope Assembly (OTA) for achieving the OTA optical performance Low transfer characteristics for mechanical disturbance from attitude sensors and actuators (gyros and momentum wheels) to Optical Telescope Assembly (OTA) for achieving the OTA optical performance Strict contamination control for longer life of science instruments Strict contamination control for longer life of science instruments Development of 12bit JPEG compression hardware chip for reducing the size of science data Development of 12bit JPEG compression hardware chip for reducing the size of science data
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International Collaboration - Japan: Development of OTA, XRT camera and - Japan: Development of OTA, XRT camera and control electronics, spacecraft, and control electronics, spacecraft, and launch vehicle launch vehicle - US : Development of FPP, XRT telescope, - US : Development of FPP, XRT telescope, (NASA) and EIS optics & mechanisms (NASA) and EIS optics & mechanisms - UK : Development of EIS - UK : Development of EIS (PPARC) (PPARC) - ESA : Telemetry data reception - ESA : Telemetry data reception at Svalbard (N78, Norway) at Svalbard (N78, Norway) 15 contacts/day 300-400 kbps/ave. 15 contacts/day 300-400 kbps/ave.
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Schedule up to Launch 1991: First mission concept 1991: First mission concept 1995: Submission of proposal 1995: Submission of proposal 1998: Approval by government 1998: Approval by government 1999: Start of mission design 1999: Start of mission design 2001: Proto model test 2001: Proto model test 2002: Structure and thermal model tests 2002: Structure and thermal model tests 2003: Fabrication of flight models 2003: Fabrication of flight models 2004: Electrical and mechanical interface check 2004: Electrical and mechanical interface check 2005: Assembly and Environmental Test 2005: Assembly and Environmental Test 2006: Final performance test 2006: Final performance test 2006 Sep 23: Launch of spacecraft 2006 Sep 23: Launch of spacecraft
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Verification Test Mechanical load test Thermal vacuum test Door deployment test 2005 Oct 2006 Mar
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Launch ! 2006 Sep 23 06:36 JST
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Hinode Operation after Launch 2006 Sep 23: Launch 2006 Sep 23: Launch Oct 03: Finish orbit control to achieve sun- Oct 03: Finish orbit control to achieve sun- synchronous orbit as scheduled synchronous orbit as scheduled Oct 23: Start XRT PV observations Oct 23: Start XRT PV observations Oct 25: Start SOT PV observations Oct 25: Start SOT PV observations Oct 28: Start EIS PV observations Oct 28: Start EIS PV observations PV: Post-launch Verification PV: Post-launch Verification End of Nov: Partially start initial observations End of Nov: Partially start initial observations 2007 Mar: 2007 Mar: Start observations that are proposed from the outside of the Hinode team. Start observations that are proposed from the outside of the Hinode team. 2007 May 27: All Hinode data are opened to world-wide solar physics community. 2007 May 27: All Hinode data are opened to world-wide solar physics community.
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SOT: First Press Release Image Solar photosphere seen at 430 nm. Small bright points between granules are clearly seen. 10 4 km
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XRT: First Press Release Image
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EIS: First Press Release Image
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Summary The launch and PV-observations were successful. The launch and PV-observations were successful. The spacecraft operation by scientists is now stable. The spacecraft operation by scientists is now stable. We are moving to initial science observations. We are moving to initial science observations. Joint observations with ground-based observatories & other spacecrafts, and collaboration of science analysis with foreign scientists will be started after March 2007 to achieve Hinode science goals. Joint observations with ground-based observatories & other spacecrafts, and collaboration of science analysis with foreign scientists will be started after March 2007 to achieve Hinode science goals.
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