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TABLE OF CONTENTS

NuSTAR is a mission to image the high energy X-ray region of the electromagnetic spectrum, searching for black holes, mapping supernova explosions, and studying extreme active galaxies. It will also study the origin of cosmic rays and perform follow-up observations to discoveries by other telescopes.

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TABLE OF CONTENTS

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  1. Nuclear Spectroscopic Telescope ArrayNuSTAR TABLE OF CONTENTS Table of Contents: Mission Overview Timeline Scientific Objectives Spacecraft Launch Vehicle Equipment

  2. MISSION OVERVIEW The NuSTAR mission will deploy the first focusing telescopes to image the sky in the high energy X-ray (6 - 79 ken) region of theelectromagnetic spectrum. NuSTAR will search for black holes, map supernova explosions, and study the most extreme active galaxies. v Artist's concept of NuSTAR on orbit.

  3. TIMELINE • March 14, 2012 – NuStar launches. • Mission length – 2 years. • Orbit Height – 550 Kilometers. • NuSTAR will launch into a low-Earth orbit, on a Pegasus XL rocket Back to Table of Contents

  4. SCIENTIFIC OBJECTIVES v During a two-year primary mission phase, NuSTAR will map selected regions of the sky in order to: take a census of collapsed stars and black holes of different sizes by surveying regions surrounding the center of our Milky Way Galaxy and performing deep observations of the extragalactic sky; map recently-synthesized material in young supernova remnants to understand how stars explode and how elements are created; and understand what powers relativistic jets of particles from the most extreme active galaxies hosting supermassive black holes. v v v

  5. SCIENTIFIC OBJECTIVES v NuSTAR will also study the origin of cosmic rays and the extreme physics around collapsed stars while responding to targets of opportunity including supernovae and gamma-ray bursts. NuSTAR will perform follow-up observations to discoveries made by Chandra and Spitzer and will team with GLAST, making simultaneous observations which will greatly enhancing GLAST's science return. v v v Back to Table of Contents

  6. SPACECRAFT The NuSTAR instrument consists of two co-aligned grazing incidencetelescopes with specially coated optics and Cadmium Zinc Telluride (CdZnTe) detectors that extend sensitivity to higher energies as compared to previous missions such as Chandra and XMM.

  7. SPACECRAFT After launching into orbit, the NuSTAR telescope extends to achieve a 10-meter focal length. The observatory will provide a combination of sensitivity, spatial, and spectral resolution factors of 10 to 100 improved over previous missions that have operated at these X-ray energies. Back to Table of Contents

  8. Launch Vehicle NuSTAR will launch into a low-Earth, near-equatorial orbit on a Pegasus XL rocket from the Kwajalein Atoll. The Pegasus launch vehicle, built by Orbital Sciences Corporation, relies on a unique air-launch system with the rocket released at approximately 40,000 feet from the "Stargazer" L-1011 aircraft. The rocket then free-falls in a horizontal position for five seconds before igniting its three-stage rocket motor. Back to Table of Contents

  9. Launch Vehicle The Pegasus launch from Kwajalein will position NuSTAR in a low-Earth equatorial orbit at an altitude of approximately 550 km and an inclination of 6 degrees. Back to Table of Contents

  10. EQUIPMENT INDEX • Optics • Deployable Mast • Focal Plane/Detectors Back to Table of Contents

  11. Optics NuSTAR employs two grazing incidence focusing optics each of which consists of 133 concentric shells. Using epoxy and graphite spacers, the layers are built up, approximately one layer per day. Each unit is 47.2 cm (18.6 inches) long, 19.1 (7.5 inches) cm in diameter and weighs 31 kg (69 pounds). The first NuSTAR optics module (“FM0”) completed on August 5, 2010.

  12. Deployable Mast Essential to the NuSTAR design is a deployable mast which extends to 10 meters (30 feet) after launch. This mast will separate the NuSTAR X-ray optics from the detectors, a necessity to achieve the long focal length required by the optics design. Back to Equipment Index

  13. Deployable Mast In order to assure that the NuSTAR optics are well-aligned with the detectors, an adjustment mechanism will be deployed on the mast. This mechanism will be used once at the beginning of the mission to align the telescope. In order to measure deflections of the mast, NuSTAR uses a laser metrology system consisting of two lasers on the optics end that are pointed at three light-sensing detectors at the detector end of the telescope. Measurements from the laser metrology system will be used to correct the X-ray images, which would otherwise be blurred by the motion of the mast. Back to Equipment Index

  14. Focal Plane/Detectors NuSTAR has two detector units, each at the focus of one of the two co-aligned NuSTAR optics units. The optical units observe the same area of sky, and the two images are combined on the ground.  The focal planes are each comprised of four 32×32 pixel Cadmium-Zinc-Tellurium (CdZnTe, or CZT) detectors. Back to Equipment Index

  15. LINKS • NuSTAR (CalTech) • NuSTAR (NASA) • Nuclear Spectroscopic Telescope Array (Wikidepida) Back to Table of Contents

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