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Overview of AtomDB : What do we Need Now?

AtomDB Workshop 2012. Overview of AtomDB : What do we Need Now?. Randall Smith Smithsonian Astrophysical Observatory. Building a Firm Connection Between “ Laboratory ” and “ Astrophysics ” …. will include thorough reading of these reports…. New Worlds, New Horizons.

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Overview of AtomDB : What do we Need Now?

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  1. AtomDB Workshop 2012 Overview of AtomDB: What do we Need Now? Randall Smith Smithsonian Astrophysical Observatory

  2. Building a Firm Connection Between “Laboratory” and “Astrophysics”… will include thorough reading of these reports…

  3. New Worlds, New Horizons

  4. NWNH Decadal Recommendations • Basic nuclear, ionic, atomic, and molecular physics to support interpretation of data from JWST and future missions [e.g. Herschel, SPICA, IXO]; $2M/year additional funding recommended [25% increase]. (p.220) • “NASA and NSF support for laboratory astrophysics … should continue at current or higher levels over the coming decade because laboratory astrophysics is vital for optimizing the science return from current and planned facilities.” • “Missions and facilities, including DOE projects, that will require significant amounts of new laboratory research results to reach their science goals should include within their program budgets adequate funding for the necessary experimental and theoretical investigations.”

  5. NWNHOrigins Study of the origin and evolution of astronomical objects including planets, stars, galaxies, and the universe itself can elucidate our origins. • How did the universe begin? • What were the first objects to light up the universe and when did they do it? • How do cosmic structures form and evolve? • What are the connections between dark and luminous matter? • What is the fossil record of galaxy assembly and evolution from the first stars to the present? • How do stars form? • How do circumstellar disks evolve and form planetary systems?

  6. TW Hya: Accretion & X-rays TW Hya: A 10 Myr old “Sun” that is still accreting material Accretion apparently heats a significant amount of coronal gas well beyond the shock itself. Determining this required measuring the temperatures, densities, and velocities involved. NWNH Origins: How do stars form? Brickhouse+ 2010

  7. TW Hya with Chandra HETG Major atomic physics needs were H-like, He-like, and Fe (and to a lesser extent Ni) L-shell line data. 489 ks (~8 days of observing) Brickhouse+ 2010

  8. Helium-like Diagnostics Brickhouse+ 2010 While the temperature diagnostics for Mg XI, Ne IX, and O VII all give roughly the same result, the density diagnostics are significantly different, especially for O VII, leading to the primary result.

  9. NWNHCosmic Order The combination of basic physical processes can often lead to surprisingly complex results and produce much of the intriguing cosmic order. • How do baryons cycle in and out of galaxies, and what do they do while they are there? • What are the flows of matter and energy in the circumgalactic medium? • What controls the mass-energy-chemical cycles within galaxies? • How do black holes grow, radiate, and influence their surroundings? • How do rotation and magnetic fields affect stars? • How do the lives of massive stars end? • How diverse are planetary systems? • What are the progenitors of Type IaSNeand how do they explode? • Do habitable worlds exist around other stars, and can we identify the telltale signs of life on an exoplanet?

  10. The Velocity of Intragalactic Gas in Elliptical Galaxies NGC 5813 NGC 5044 NASA/CXC/U. Ohio/T.Statler & S.Diehl NASA/CXC/SAO/S.Randall et al. NWNH Cosmic Origins: What are the flows of matter and energy in the circumgalactic medium?

  11. Fe XVII Resonance Scattering Fe l15.01Å has an oscillator strength of ~2.5, so a dense, low-turbulence environment will cause scattering that increases the observed ratio. But how to explain NGC5044 with AtomDB v2.0.1 models?

  12. Fe XVII: Where are we now? Gillaspy+ 2010 Fe XVII 3C/3D from the point of view of observational data and various calculations

  13. NWNH Frontiers of Knowledge New fundamental physics, chemistry, and biology can be revealed by astronomical measurements, experiments, or theory and hence push the frontiers of human knowledge. • Why is the Universe accelerating? • What is dark matter? • What are the properties of neutrinos? • What controls the mass, radius, and spin of compact stellar remnants?

  14. Just how Standard are Type IaSNe? Riess+ 2004 The evidence shows that the Universe is accelerating; NWNH carefully notes the next question is “why?” Enter the era of precision cosmology, with associated improvements in measurements, calibration, and models. Calan–Tololo supernova survey data; https://www.llnl.gov/str/SepOct08/hoffman.html

  15. Physics of Type Ia SNe Suzaku 100ks Tycho observation shows Mn and Cr fluorescence lines from partially-ionized material. Relevant atomic parameters had to be estimated. Badenes+(2008) considered model SNIa explosions with different neutron excesses and various classes of explosions, concluding that Tycho’s progenitor had near-solar or supersolar metallicity NWNH Frontiers of Knowledge : Why is the Universe accelerating? Badenes et al 2008

  16. Moving beyond NWHN…

  17. What Do Astronomers Want? (from Lab Astro) • Precise and accurate data for calibration and interpretation. Ordered by importance: • Wavelengths • Line widths/shapes/blends • Fluxes • Reliable and practical estimates of data accuracy(especially in X-ray astronomy!)

  18. Calibration: Fluorescent Lines Bandler+ 2010 The fluorescent lines from radioactive sources are complex of many lines. Hoelzer+ 1997 Line widths measured by current calorimeters are dominated by the natural line widths – which are not known for many useful elements!

  19. Calibration: Absorption Cross Sections Lee et al 09 Absorption edges and related features still need a lot of work…

  20. Calibration: Wavelengths Fit using ‘raw’ HULLAC wavelengths Fit using lab (Brown et al. 1998) wavelengths Fit using newly calculated wavelengths Kotochigova+ 2010 • By combining laboratory measurements and theoretical structure calculations, can get highly accurate (few mÅ) wavelengths. • Detectors with R>1000 require this kind of accuracy!

  21. Sensitivity Testing Labs determine statistical and systematic errors as part of all measurements; care is needed in interpreting systematic errors. Theoretical calculations can use Monte-Carlo methods, varying the input atomic structure or calculation size to estimate sensitivities. While care is again needed, these are better than providing no estimate at all. See also Bravo & Martínez-Pinedo (2012)

  22. Conclusions Point #1: We must maintain a tight connection between identified astrophysical questions and lab astro measurements and calculations.

  23. Conclusions Point #2: 15 years ago, we knew existing X-ray spectral models would not survive the imminent arrival of new capabilities from Chandra and XMM-Newton • Inadequate Fe L shell models with missing lines and inaccurate wavelengths • Out of date models for H, He-like ions

  24. Conclusions Point #3: Astro-H will soon increase the effective area of X-ray spectroscopy 100-fold • Some data are still missing: Ni L-shell, Fluorescent lines from select ions, Fe L-shell wavelengths, BUT • Current approach of assuming zero spectral model errors will lead to data that cannot be interpreted.

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