The Resource Astronomical spectroscopy : an introduction to the atomic and molecular physics of astronomical spectra, Jonathan Tennyson

Astronomical spectroscopy : an introduction to the atomic and molecular physics of astronomical spectra, Jonathan Tennyson

Label
Astronomical spectroscopy : an introduction to the atomic and molecular physics of astronomical spectra
Title
Astronomical spectroscopy
Title remainder
an introduction to the atomic and molecular physics of astronomical spectra
Statement of responsibility
Jonathan Tennyson
Creator
Subject
Language
eng
Cataloging source
DLC
http://library.link/vocab/creatorName
Tennyson, Jonathan
Dewey number
522.6/7
Illustrations
illustrations
Index
index present
LC call number
QB465
LC item number
.T46 2011
Literary form
non fiction
Nature of contents
bibliography
http://library.link/vocab/subjectName
  • Astronomical spectroscopy
  • Atomic spectroscopy
  • Molecular spectroscopy
Label
Astronomical spectroscopy : an introduction to the atomic and molecular physics of astronomical spectra, Jonathan Tennyson
Instantiates
Publication
Bibliography note
Includes bibliographical references (p. 215-216) and index
Contents
  • Nature of Spectra
  • Helium Spectra
  • 5.1.
  • He I and He II Spectra
  • 5.2.
  • Selection Rules for Complex Atoms
  • 5.3.
  • Observing Forbidden Lines
  • 5.4.
  • Grotrian Diagrams
  • 5.5.
  • 2.1.
  • Potential Felt by Electrons in Complex Atoms
  • 5.6.
  • Emissions of Helium-Like Ions
  • 6.
  • Alkali Atoms
  • 6.1.
  • Sodium
  • 6.2.
  • Spin-Orbit Interactions
  • 6.3.
  • Transitions
  • Fine Structure Transitions
  • 6.4.
  • Astronomical Sodium Spectra
  • 6.5.
  • Other Alkali Metal-Like Spectra
  • 7.
  • Spectra of Nebulae
  • 7.1.
  • Nebulium
  • 7.2.
  • 2.2.
  • Bowen Mechanism
  • 7.3.
  • Two Valence Electrons
  • 7.4.
  • Autoionisation and Recombination
  • 8.
  • Spectra in Magnetic Fields
  • 8.1.
  • Uniform Magnetic Field
  • 8.2.
  • Absorption and Emission
  • Strong Magnetic Field
  • 8.3.
  • Weak Magnetic Field
  • 8.3.1.
  • normal Zeeman effect
  • 8.3.2.
  • anomolous Zeeman effect
  • 8.4.
  • Spectra in Magnetic Field
  • 9.
  • 2.3.
  • X-Ray Spectra
  • 9.1.
  • Inner Shell Processes
  • 9.2.
  • Solar Corona
  • 9.3.
  • Structure of Highly Ionised Atoms
  • 9.4.
  • Isotope Effects
  • 10.
  • Other Measures of Transition Probabilities
  • Molecular Structure
  • 10.1.
  • Born-Oppenheimer Approximation
  • 10.2.
  • Electronic Structure of Diatomics
  • 10.2.1.
  • Labelling of electronic states
  • 10.2.2.
  • Symmetry
  • 10.2.3.
  • 2.4.
  • State labels
  • 10.3.
  • Schrodinger Equation
  • 10.3.1.
  • Nuclear motion in diatomic molecules
  • 10.4.
  • Fractionation
  • 10.5.
  • Vibration-Rotation Energy Levels
  • 10.6.
  • Stimulated Emission
  • Temperature Effects
  • 10.6.1.
  • Rotational state populations
  • 10.6.2.
  • Vibrational state populations
  • 10.6.3.
  • Electronic state populations
  • 11.
  • Rotational Spectra
  • 11.1.
  • 2.5.
  • Rotational Structure of Polyatomic Molecules
  • 11.2.
  • Selection Rules: Pure Rotational Transitions
  • 11.3.
  • Selection Rules
  • 11.4.
  • Isotope Effects
  • 11.5.
  • Rotational Spectra of Other Molecules
  • 11.6.
  • Machine generated contents note:
  • Optical Depth
  • Rotational Spectra of Molecular Hydrogen
  • 11.7.
  • Maser Emissions
  • 12.
  • Vibration-Rotation Spectra
  • 12.1.
  • Vibrations in Polyatomic Molecules
  • 12.2.
  • Vibrational Transitions
  • 12.2.1.
  • 2.6.
  • Structure of the spectrum
  • 12.2.2.
  • Isotope effects
  • 12.2.3.
  • Hydrogen molecule vibrational spectra
  • 12.3.
  • Astronomical Spectra
  • 13.
  • Electronic Spectra of Diatomic Molecules
  • 13.1.
  • Critical Density
  • Electronic Transitions
  • 13.2.
  • Selection Rules
  • 13.2.1.
  • Vibrational selection rules
  • 13.2.2.
  • Rotational selection rules
  • 13.3.
  • Transition Frequencies
  • 13.4.
  • 2.7.
  • Astronomical Spectra
  • 13.5.
  • Non-1Σ Electronic States
  • Wavelength or Frequency?
  • 2.8.
  • Electromagnetic Spectrum
  • 3.
  • Atomic Hydrogen
  • 3.1.
  • 1.
  • Overview
  • 3.2.
  • Schrodinger Equation of Hydrogen-Like Atoms
  • 3.3.
  • Reduced Mass
  • 3.4.
  • Atomic Units
  • 3.5.
  • Wavefunctions for Hydrogen
  • 3.6.
  • Why Record Spectra of Astronomical Objects?
  • Energy Levels and Quantum Numbers
  • 3.7.
  • H-Atom Discrete Spectra
  • 3.8.
  • H-Atom Spectra in Different Locations
  • 3.8.1.
  • Balmer series
  • 3.8.2.
  • Lyman series
  • 3.8.3.
  • 1.1.
  • Infrared lines
  • 3.9.
  • H-Atom Continuum Spectra
  • 3.9.1.
  • Processes
  • 3.9.2.
  • H-atom emission in H II regions
  • 3.10.
  • Radio Recombination Lines
  • 3.11.
  • Historical Introduction
  • Radio Recombination Lines for Other Atoms
  • 3.12.
  • Angular Momentum Coupling in the Hydrogen Atom
  • 3.13.
  • Fine Structure of Hydrogen
  • 3.14.
  • Hyperfine Structure in the H Atom
  • 3.15.
  • Allowed Transitions
  • 3.16.
  • 1.2.
  • Hydrogen in Nebulae
  • 4.
  • Complex Atoms
  • 4.1.
  • General Considerations
  • 4.2.
  • Central Field Model
  • 4.3.
  • Indistinguishable Particles
  • 4.4.
  • What One Can Learn from Studying Spectra
  • Electron Configurations
  • 4.5.
  • Periodic Table
  • 4.6.
  • Ions
  • 4.7.
  • Angular Momentum in Complex Atoms
  • 4.7.1.
  • L-S or Russell-Saunders coupling
  • 4.7.2.
  • 2.
  • j-j coupling
  • 4.7.3.
  • Why two coupling schemes?
  • 4.8.
  • Spectroscopic Notation
  • 4.9.
  • Parity of the Wavefunction
  • 4.10.
  • Terms and Levels in Complex Atoms
  • 5.
Dimensions
23 cm.
Edition
2nd ed.
Extent
x, 223 p.
Isbn
9789814291972
Isbn Type
(pbk.)
Lccn
2011411319
Other physical details
ill. (some col.)
System control number
  • (CaMWU)u2410648-01umb_inst
  • 2433966
  • (Sirsi) i9789814291972
  • (OCoLC)464589436
Label
Astronomical spectroscopy : an introduction to the atomic and molecular physics of astronomical spectra, Jonathan Tennyson
Publication
Bibliography note
Includes bibliographical references (p. 215-216) and index
Contents
  • Nature of Spectra
  • Helium Spectra
  • 5.1.
  • He I and He II Spectra
  • 5.2.
  • Selection Rules for Complex Atoms
  • 5.3.
  • Observing Forbidden Lines
  • 5.4.
  • Grotrian Diagrams
  • 5.5.
  • 2.1.
  • Potential Felt by Electrons in Complex Atoms
  • 5.6.
  • Emissions of Helium-Like Ions
  • 6.
  • Alkali Atoms
  • 6.1.
  • Sodium
  • 6.2.
  • Spin-Orbit Interactions
  • 6.3.
  • Transitions
  • Fine Structure Transitions
  • 6.4.
  • Astronomical Sodium Spectra
  • 6.5.
  • Other Alkali Metal-Like Spectra
  • 7.
  • Spectra of Nebulae
  • 7.1.
  • Nebulium
  • 7.2.
  • 2.2.
  • Bowen Mechanism
  • 7.3.
  • Two Valence Electrons
  • 7.4.
  • Autoionisation and Recombination
  • 8.
  • Spectra in Magnetic Fields
  • 8.1.
  • Uniform Magnetic Field
  • 8.2.
  • Absorption and Emission
  • Strong Magnetic Field
  • 8.3.
  • Weak Magnetic Field
  • 8.3.1.
  • normal Zeeman effect
  • 8.3.2.
  • anomolous Zeeman effect
  • 8.4.
  • Spectra in Magnetic Field
  • 9.
  • 2.3.
  • X-Ray Spectra
  • 9.1.
  • Inner Shell Processes
  • 9.2.
  • Solar Corona
  • 9.3.
  • Structure of Highly Ionised Atoms
  • 9.4.
  • Isotope Effects
  • 10.
  • Other Measures of Transition Probabilities
  • Molecular Structure
  • 10.1.
  • Born-Oppenheimer Approximation
  • 10.2.
  • Electronic Structure of Diatomics
  • 10.2.1.
  • Labelling of electronic states
  • 10.2.2.
  • Symmetry
  • 10.2.3.
  • 2.4.
  • State labels
  • 10.3.
  • Schrodinger Equation
  • 10.3.1.
  • Nuclear motion in diatomic molecules
  • 10.4.
  • Fractionation
  • 10.5.
  • Vibration-Rotation Energy Levels
  • 10.6.
  • Stimulated Emission
  • Temperature Effects
  • 10.6.1.
  • Rotational state populations
  • 10.6.2.
  • Vibrational state populations
  • 10.6.3.
  • Electronic state populations
  • 11.
  • Rotational Spectra
  • 11.1.
  • 2.5.
  • Rotational Structure of Polyatomic Molecules
  • 11.2.
  • Selection Rules: Pure Rotational Transitions
  • 11.3.
  • Selection Rules
  • 11.4.
  • Isotope Effects
  • 11.5.
  • Rotational Spectra of Other Molecules
  • 11.6.
  • Machine generated contents note:
  • Optical Depth
  • Rotational Spectra of Molecular Hydrogen
  • 11.7.
  • Maser Emissions
  • 12.
  • Vibration-Rotation Spectra
  • 12.1.
  • Vibrations in Polyatomic Molecules
  • 12.2.
  • Vibrational Transitions
  • 12.2.1.
  • 2.6.
  • Structure of the spectrum
  • 12.2.2.
  • Isotope effects
  • 12.2.3.
  • Hydrogen molecule vibrational spectra
  • 12.3.
  • Astronomical Spectra
  • 13.
  • Electronic Spectra of Diatomic Molecules
  • 13.1.
  • Critical Density
  • Electronic Transitions
  • 13.2.
  • Selection Rules
  • 13.2.1.
  • Vibrational selection rules
  • 13.2.2.
  • Rotational selection rules
  • 13.3.
  • Transition Frequencies
  • 13.4.
  • 2.7.
  • Astronomical Spectra
  • 13.5.
  • Non-1Σ Electronic States
  • Wavelength or Frequency?
  • 2.8.
  • Electromagnetic Spectrum
  • 3.
  • Atomic Hydrogen
  • 3.1.
  • 1.
  • Overview
  • 3.2.
  • Schrodinger Equation of Hydrogen-Like Atoms
  • 3.3.
  • Reduced Mass
  • 3.4.
  • Atomic Units
  • 3.5.
  • Wavefunctions for Hydrogen
  • 3.6.
  • Why Record Spectra of Astronomical Objects?
  • Energy Levels and Quantum Numbers
  • 3.7.
  • H-Atom Discrete Spectra
  • 3.8.
  • H-Atom Spectra in Different Locations
  • 3.8.1.
  • Balmer series
  • 3.8.2.
  • Lyman series
  • 3.8.3.
  • 1.1.
  • Infrared lines
  • 3.9.
  • H-Atom Continuum Spectra
  • 3.9.1.
  • Processes
  • 3.9.2.
  • H-atom emission in H II regions
  • 3.10.
  • Radio Recombination Lines
  • 3.11.
  • Historical Introduction
  • Radio Recombination Lines for Other Atoms
  • 3.12.
  • Angular Momentum Coupling in the Hydrogen Atom
  • 3.13.
  • Fine Structure of Hydrogen
  • 3.14.
  • Hyperfine Structure in the H Atom
  • 3.15.
  • Allowed Transitions
  • 3.16.
  • 1.2.
  • Hydrogen in Nebulae
  • 4.
  • Complex Atoms
  • 4.1.
  • General Considerations
  • 4.2.
  • Central Field Model
  • 4.3.
  • Indistinguishable Particles
  • 4.4.
  • What One Can Learn from Studying Spectra
  • Electron Configurations
  • 4.5.
  • Periodic Table
  • 4.6.
  • Ions
  • 4.7.
  • Angular Momentum in Complex Atoms
  • 4.7.1.
  • L-S or Russell-Saunders coupling
  • 4.7.2.
  • 2.
  • j-j coupling
  • 4.7.3.
  • Why two coupling schemes?
  • 4.8.
  • Spectroscopic Notation
  • 4.9.
  • Parity of the Wavefunction
  • 4.10.
  • Terms and Levels in Complex Atoms
  • 5.
Dimensions
23 cm.
Edition
2nd ed.
Extent
x, 223 p.
Isbn
9789814291972
Isbn Type
(pbk.)
Lccn
2011411319
Other physical details
ill. (some col.)
System control number
  • (CaMWU)u2410648-01umb_inst
  • 2433966
  • (Sirsi) i9789814291972
  • (OCoLC)464589436

Library Locations

  • Albert D. Cohen Management LibraryBorrow it
    181 Freedman Crescent, Winnipeg, MB, R3T 5V4, CA
    49.807878 -97.129961
  • Architecture/Fine Arts LibraryBorrow it
    84 Curry Place, Winnipeg, MB, CA
    49.807716 -97.136226
  • Archives and Special CollectionsBorrow it
    25 Chancellors Circle (Elizabeth Dafoe Library), Room 330, Winnipeg, MB, R3T 2N2, CA
    49.809961 -97.131878
  • Bibliothèque Alfred-Monnin (Université de Saint-Boniface)Borrow it
    200, avenue de la Cathédrale, Local 2110, Winnipeg, MB, R2H 0H7, CA
    49.888861 -97.119735
  • Bill Larson Library (Grace Hospital)Borrow it
    300 Booth Drive, G-227, Winnipeg, MB, R3J 3M7, CA
    49.882400 -97.276436
  • Carolyn Sifton - Helene Fuld Library (St. Boniface General Hospital)Borrow it
    409 Tache Avenue, Winnipeg, MB, R2H 2A6, CA
    49.883388 -97.126050
  • Concordia Hospital LibraryBorrow it
    1095 Concordia Avenue, Winnipeg, MB, R2K 3S8, CA
    49.913252 -97.064683
  • Donald W. Craik Engineering LibraryBorrow it
    75B Chancellors Circle (Engineering Building E3), Room 361, Winnipeg, MB, R3T 2N2, CA
    49.809053 -97.133292
  • E.K. Williams Law LibraryBorrow it
    224 Dysart Road, Winnipeg, MB, R3T 5V4, CA
    49.811829 -97.131017
  • Eckhardt-Gramatté Music LibraryBorrow it
    136 Dafoe Road (Taché Arts Complex), Room 257, Winnipeg, MB, R3T 2N2, CA
    49.807964 -97.132222
  • Elizabeth Dafoe LibraryBorrow it
    25 Chancellors Circle, Winnipeg, MB, R3T 2N2, CA
    49.809961 -97.131878
  • Fr. H. Drake Library (St. Paul's College)Borrow it
    70 Dysart Road, Winnipeg, MB, R3T 2M6, CA
    49.810605 -97.138184
  • J.W. Crane Memorial Library (Deer Lodge Centre)Borrow it
    2109 Portage Avenue, Winnipeg, MB, R3J 0L3, CA
    49.878000 -97.235520
  • Libraries Annex (not open to the public; please see web page for details)Borrow it
    25 Chancellors Circle (in the Elizabeth Dafoe Library), Winnipeg, MB, R3T 2N2, CA
    49.809961 -97.131878
  • Neil John Maclean Health Sciences LibraryBorrow it
    727 McDermot Avenue (Brodie Centre), 200 Level, Winnipeg, MB, R3E 3P5, CA
    49.903563 -97.160554
  • Sciences and Technology LibraryBorrow it
    186 Dysart Road, Winnipeg, MB, R3T 2M8, CA
    49.811526 -97.133257
  • Seven Oaks General Hospital LibraryBorrow it
    2300 McPhillips Street, Winnipeg, MB, R2V 3M3, CA
    49.955177 -97.148865
  • Sister St. Odilon Library (Misericordia Health Centre)Borrow it
    99 Cornish Avenue, Winnipeg, MB, R3C 1A2, CA
    49.879592 -97.160425
  • St. John's College LibraryBorrow it
    92 Dysart Road, Winnipeg, MB, R3T 2M5, CA
    49.811242 -97.137156
  • Victoria General Hospital LibraryBorrow it
    2340 Pembina Highway, Winnipeg, MB, R3T 2E8, CA
    49.806755 -97.152739
  • William R Newman Library (Agriculture)Borrow it
    66 Dafoe Road, Winnipeg, MB, R3T 2R3, CA
    49.806936 -97.135525
Processing Feedback ...