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Atomic and Molecular Radiation Physics: From Astronomy To Biomedicine Light and Matter  Spectroscopy Generalized interactions  Radiation Atomic physics.

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Presentation on theme: "Atomic and Molecular Radiation Physics: From Astronomy To Biomedicine Light and Matter  Spectroscopy Generalized interactions  Radiation Atomic physics."— Presentation transcript:

1 Atomic and Molecular Radiation Physics: From Astronomy To Biomedicine Light and Matter  Spectroscopy Generalized interactions  Radiation Atomic physics Astrophysics Plasma physics Molecular physics Biophysics

2 Eta Carinae Nebula Massive Stellar Eruption Binary Star System Symbiotic Star ~100 M(Sun) ~1,000,000 L(Sun) Pre-supernova phase

3 Imaging vs. Spectroscopy Imaging  Pictures Spectroscopy  Microscopic (or Nanoscopic) science of light and matter Pictures are incomplete at best, and deceptive at worst

4 Image + Spectrum

5 Spectrum of Eta Carinae: Iron Lines

6 NGC 5548, central region, spectral bar code

7 X-Ray Astronomy: Evidence for Black Hole Relativistic Broadening of Iron K  (6.4 keV) 2p  1s transition array Due to gravitational potential of the black hole photons lose energy Asymmetric broadening at decreasing photon energies < 6.4 keV

8 CATSCAN: Image Depends on Viewing Angle Woman holding a pineapple if viewed from the right; Or a banana if viewed from the front N.B. The Image is formed by ABSORPTION not EMISSION, as in an X-ray NEED 3D IMAGE  CATSCAN

9 Biophysics: Imaging  Spectroscopy Spectroscopy is far more powerful than imaging “A spectrum is worth a thousand pictures” Every element or object in the Universe has unique spectral signature (like DNA) Radiation absorption and emission highly efficient at resonant energies corresponding to atomic transitions in heavy element (high-Z) nanoparticles embedded in tumors Spectroscopic imaging, diagnostics, and therapy

10 How are X-rays produced? Roentgen X-ray tube  Cathode + anode Electrons Cathode Tungsten Anode X-ray Energy Intensity Bremsstrahlung Radiation Peak Voltage kVp Medical X-Rays: Imaging and Therapy 6 MVp LINAC Radiation Therapy 100 kVp Diagnostics

11 High-Energy-Density Physics (HEDP) Laboratory and astrophysical sources Energetic phenomena  AGN, ICF, lasers Temperature-Density regimes  Fig. (1.3) Opacity: Radiation  Matter Opacity Project, Iron Project Iron Opacity Project  Theoretical work related to the Z-pinch fusion device at Sandia, creating stellar plasmas in the lab and measuring iron opacity

12 HED Plasma at Solar Interior conditions: ICF Z-Pinch Iron Opacity Measurements Iron Mix Z-pinch

13 Temperature-Density In HED Environments Adapted From “Atomic Astrophysics And Spectroscopy” (Pradhan and Nahar, (Cambridge 2011) Non-HED HED Z ISM

14 Light: Electromagnetic Spectrum From Gamma Rays to Radio Gamma rays are the most energetic (highest frequency, shortest wavelength), radio waves are the least energetic. Astronomy Medicine

15 Light Electromagnetic radiation: Gamma – Radio Units: 1 nm = 10 A, 10000 A = 1  m Nuclear  Gamma Atomic  X-ray, UV, O, IR, Radio (Fig. 1.2) UV  NUV (3000-4000 A), FUV (1200-2000 A), XUV(100-1200 A) (Ly  1215 A, Lyman edge 912 A ) O  4000-7000 A (Balmer H  : 6563-3650 A) IR  NIR (JHK: 1.2, 1.6, 2.0  m ), FIR (5-300  m) Ground-based astronomy: UBVGRIJHK Bands Molecular  sub-mm, Microwave (cm), Radio (m – km) Gamma, X-ray  keV, MeV, GeV Units: Rydbergs  Ang (Eq. 1.27)

16 Matter Atoms, molecules, clusters, ions, plasma Astrophysics  ISM, Nebulae, Stars, AGN Compact objects  White dwarfs, Neutron stars (degenerate fermions) Black holes ? Laboratory  BEC (bosons; viz. alkali atom condensates)

17 Universal Matter-Energy Distribution Cosmic abundances Mass fractions  X, Y, Z (H, He, “metals”) Solar composition  X: 0.7, Y: 0.28, Z: 0.02 All visible matter ~4% of the Universe Dark Matter ~ 22% Dark Energy ~ 74%

18 Spectroscopy (Ch. 1, AAS) Light + Matter  Spectroscopy Fraunhofer lines  Fig. 1.1 D2-lines Optical H,K lines of Ca II (UV h,k lines of Mg II) Stellar luminosity classes and spectral types Atomic LS coupling (Russell-Saunders 1925) Configurations  LS, LSJ, LSJF (Ch. 2) Atomic structure is governed by the Pauli exclusion principle (Ch. 2), more generally by the Antisymmetry postulate

19 Energy-Matter Micro-distributions Blackbody, luminosity, Planck function (Eqs. 1.4-1.6) Example: The Sun (Figs. 1.4, 1.5) Quantum statistics Particle distributions: Maxwell, Maxwell-Boltzmann Fermions, Bosons: Fermi-Dirac (FD), Bose-Einstein (BE) FD, BE  Maxwellian, as T increases Entropy: Evaporate from the Fermi-sea

20 Spectrophotometry Broadband “colors”  high-res spectroscopy Spectrophotometry maps an object in one spectral line, e.g. map the entire disk of the Sun in O III green line at 5007 A (filter out rest)

21 Syllabus and Overview Methodology, approximations, applications Atomic structure and processes: unified view Radiation scattering, emission, absorption Plasma interactions:  Line Broadening, Equation-of-state, opacities Nebulae, stars, galaxies, cosmology Molecular structure and spectra Biophysics and nanophysics

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