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AtomNeb IDL Library

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Description

AtomNeb-idl is a library written in Interactive Data Language (IDL)/GNU Data Language (GDL) for reading atomic data from AtomNeb, which is a database containing atomic data stored in the Flexible Image Transport System (FITS) file format for collisionally excited lines and recombination lines typically observed in spectra of ionized gaseous nebulae. The AtomNeb database were generated for use in proEQUIB, pyEQUIB, and other nebular spectral analysis tools.

Collisionally Excited Lines

AtomNeb for collisionally excited lines contains sets of atomic datasets, which include energy levels (Ej), collision strengths (Ωij), and transition probabilities (Aij) of the most ions commonly observed in ionized nebulae.

The atomic datasets for collisionally excited lines are as follows:

Each dataset contains the following atomic data FITS files: AtomElj.fits for Energy Levels (Ej), AtomOmij.fits for Collision Strengths (Ωij), and AtomAij.fits for Transition Probabilities (Aij).

Recombination Lines

AtomNeb for recombination lines contains sets of effective recombination coefficients (αeff) of recombination lines of H I, He I, He II, C I, C II, C III, C VI, N II, N III, N IV, N V, N VI, N VII, O II, O III, O IV, O V, O VI, O VIII, and Ne II ions typically observed in ionized nebulae, as well as Branching ratios (Br) of O II and N II lines.

The atomic datasets for recombination lines are as follows:

Installation

Dependent IDL Packages

This package requires the following packages:

  • To get this package with all the dependent packages, you can simply use git command as follows:
git clone --recursive https://github.com/atomneb/AtomNeb-idl
cd AtomNeb-idl/atomic-data-rc/
tar -xvf *.fits.tar.gz

Installation in IDL

  • To install the AtomNeb database and its API library in the Interactive Data Language (IDL), you need to add the path of this package directory to your IDL path. or more information about the path management in IDL, read the tips for customizing IDL program path provided by Harris Geospatial Solutions or the IDL library installation note by David Fanning in the Coyote IDL Library.
  • This package requires IDL version 7.1 or later.

Installation in GDL

  • You can install the GNU Data Language (GDL) if you do not have it on your machine:

    • Linux (Fedora):
    sudo dnf install gdl
    
    • Linux (Ubuntu):
    sudo apt-get install gnudatalanguage
    
    brew tap brewsci/science
    brew install gnudatalanguage
    
    sudo port selfupdate
    sudo port upgrade libtool
    sudo port install gnudatalanguage
    
  • To install the AtomNeb database and its API library in GDL, you need to add the path of this package directory to your .gdl_startup file in your home directory:

    !PATH=!PATH + ':/home/AtomNeb-idl/pro/'
    !PATH=!PATH + ':/home/AtomNeb-idl/externals/astron/pro/'
    

    You may also need to set GDL_STARTUP if you have not done in .bashrc (bash):

    export GDL_STARTUP=~/.gdl_startup
    

    or in .tcshrc (cshrc):

    setenv GDL_STARTUP ~/.gdl_startup
    
  • This package requires GDL version 0.9.8 or later.

How to Use

The Documentation of the IDL functions provides in detail in the API Documentation (atomneb.github.io/AtomNeb-idl/doc). There are two main categories: collisionally excited lines (CEL) and recombination lines (RC).

See Jupyter Notebooks: Notebooks.ipynb

Run Jupyter Notebooks on Binder:

  • The atomic data for collisionally excited lines (CEL) contain Energy Levels (Ej), Collision Strengths (Ωij), and Transition Probabilities (Aij). We have four atomic datasets for them: collection, chianti52, chianti60, and chianti70.

    You need to load the atomneb object class, and choose either collection, chianti52, chianti60 or chianti70 as follows:

    atm=obj_new('atomneb')
    atm->set_data_cel,'chianti70'

    Now you have access to:

    • Energy Levels (Ej):

      atom='o'
      ion='iii'
      oiii_elj_data=atm->read_elj(atom, ion, level_num=6)
      print,oiii_elj_data.J_v
      print,oiii_elj_data.Ej

      which gives:

      0.00000      1.00000      2.00000      2.00000      0.00000      2.00000
      0.00000      113.200      306.200      20273.30     43185.69     60324.80
      
    • Collision Strengths (Ωij):

      atom='o'
      ion='iii'
      oiii_omij_data=atm->read_omij(atom, ion)
      print,oiii_omij_data.level1
      print,oiii_omij_data.level2
      print,oiii_omij_data[0].strength

      which gives:

      0       1       1       1       1       ...
      0       2       3       4       5       ...
      100.0      158.50       251.20       398.10       631.0       ...
      
    • Transition Probabilities (Aij):

      atom='o'
      ion='iii'
      oiii_aij_data=atm->read_aij(atom, ion)
      print,oiii_aij_data.Aij[*,*]

      which gives:

      0.0000   2.5969e-05       0.0000   2.3220e-06      ...
      
  • The atomic data for recombination lines (RC) contain effective recombination coefficients (αeff) of emission lines from different collections: RC Collection, SH95 Collection, PPB91 Collection, PFSD12 He I data, FSL13 N II data, and SSB17 O II data.

    You need to load the atomneb object class:

    atm=obj_new('atomneb')

    Now you have access to effective recombination coefficients (αeff) of the following collections:

    • RC Collection:

      atom='c'
      ion='iii'
      cii_rc_data=atm->read_aeff_collection(atom, ion)
      n_line=size(cii_rc_data.Wavelength,/DIMENSIONS)
      for i=0,n_line[0]-1 do print,cii_rc_data[i].Wavelength, cii_rc_data[i].a, $
                                cii_rc_data[i].b, cii_rc_data[i].c, $
                                cii_rc_data[i].d, cii_rc_data[i].f

      which gives:

      914.00000      0.69280000     0.021400000    -0.016300000     -0.24310000     -0.88000000
      962.00000       1.0998000   -0.0042000000    -0.027900000     -0.22940000     -0.96560000
      997.00000      0.78210000     -0.36840000   0.00030000000     -0.12170000     -0.78740000
      ...
      
    • SH95 Collection:

      atom='h'
      ion='ii'
      hi_rc_data=atm->read_aeff_sh95(atom, ion)
      print,hi_rc_data[0].Aeff

      which gives:

      100.00000       500.00000       0.0000000   4.2140000e-27   1.7560000e-27   1.0350000e-27
      ...
      
    • PPB91 Collection:

      atom='c'
      ion='iii'
      cii_rc_data=atm->read_aeff_ppb91(atom, ion)
      n_line=size(cii_rc_data.Wavelength,/DIMENSIONS)
      for i=0,n_line[0]-1 do print,cii_rc_data[i].Ion,cii_rc_data[i].Case1, $
                                cii_rc_data[i].Wavelength, cii_rc_data[i].a, $
                                cii_rc_data[i].b, cii_rc_data[i].c, $
                                cii_rc_data[i].d, cii_rc_data[i].br, $
                                cii_rc_data[i].Q, cii_rc_data[i].y

      which gives:

      C2+A       9903.4600      0.69700000     -0.78400000       4.2050000      0.72000000       1.0000000       1.6210000
      C2+A       4267.1500       1.0110000     -0.75400000       2.5870000      0.71900000      0.95000000       2.7950000
      ...
      
    • PFSD12 He I data:

      atom='he'
      ion='ii'
      hei_rc_data=atm->read_aeff_he_i_pfsd12(atom, ion)
      hei_rc_data_wave=atm->read_aeff_he_i_pfsd12(atom, ion, /wavelength)
      print,hei_rc_data[0].Aeff

      which gives:

      5000.0000       10.000000      -25.379540      -25.058970      -25.948440      -24.651820      -25.637660
      ...
      
    • FSL13 N II data:

      atom='n'
      ion='iii'
      wavelength_range=[4400.0, 7100.0]
      nii_rc_data=atm->read_aeff_n_ii_fsl13(atom, ion, wavelength_range)
      nii_rc_data_wave=atm->read_aeff_n_ii_fsl13(atom, ion, wavelength_range, /wavelength)
      print,nii_rc_data[0].Aeff
      n_line=size(nii_rc_data_wave.Wavelength,/DIMENSIONS)
      for i=0,n_line[0]-1 do print,nii_rc_data_wave[i].Wavelength, nii_rc_data_wave[i].Tr, nii_rc_data_wave[i].Trans

      which gives:

      255.000      79.5000      47.3000      12.5000      6.20000      4.00000      2.86000
      258.000      54.4000      29.7000      7.92000      4.11000      2.72000      2.00000
      310.000      48.1000      23.7000      5.19000      2.55000      1.65000      1.21000
      434.000      50.3000      23.2000      4.71000      2.26000      1.45000      1.05000
      
      6413.23 6g - 4f2p6g G[9/2]o4 - 2p4f F[7/2]e3
      6556.32 6g - 4f2p6g G[9/2]o5 - 2p4f G[7/2]e4
      6456.97 6g - 4f2p6g G[9/2]o5 - 2p4f F[7/2]e4
      6446.53 6g - 4f2p6g F[7/2]o3 - 2p4f D[5/2]e2
      6445.34 6g - 4f2p6g F[7/2]o4 - 2p4f D[5/2]e3
      ...
      
    • SSB17 O II data: You first need to unpack rc_o_iii_SSB17_orl_case_b.fits.tar.gz, e.g.:

      tar -xvf rc_o_iii_SSB17_orl_case_b.fits.tar.gz
      

      If you need to have access to the full dataset (entire wavelengths, case A and B):

      tar -xvf rc_o_iii_SSB17.fits.tar.gz
      

      To use the full dataset:

      atm->set_Atom_RC_O_III_SSB17, /full_data

      Please note that using the entire atomic data will make your program very slow and you may need to have a higher memory on your system. Without the above comment, as default, the cose uses rc_o_iii_SSB17_orl_case_b.fits:

      atom='o'
      ion='iii'
      case1='B'
      wavelength_range=[5320.0, 5330.0]
      oii_rc_data=atm->read_aeff_o_ii_ssb17(atom, ion, case1, wavelength_range)
      oii_rc_data_wave=atm->read_aeff_o_ii_ssb17(atom, ion, case1, wavelength_range, /wavelength)
      print,oii_rc_data[0].Aeff
      n_line=size(oii_rc_data_wave.Wavelength,/DIMENSIONS)
      for i=0,n_line[0]-1 do print,oii_rc_data_wave[i].Wavelength, oii_rc_data_wave[i].lower_term, oii_rc_data_wave[i].upper_term

      which gives:

      1.64100e-30  1.60000e-30  1.56400e-30  1.54100e-30  1.52100e-30  1.50900e-30
      ...
      
      5327.17 2s22p2(1S)3p 2Po
      5325.42 2s22p2(1S)3p 2Po
      5327.18 2s22p2(1D)3d 2Ge
      5326.84 2s22p2(1D)3d 2Ge
      ...
      

Documentation

For more information on how to use the API functions from the AtomNeb IDL libray, please read the API Documentation published on atomneb.github.io/AtomNeb-idl.

References

Citation

Using the AtomNeb IDL library in a scholarly publication? Please cite these papers:

@article{Danehkar2019,
  author = {{Danehkar}, Ashkbiz},
  title = {AtomNeb: IDL Library for Atomic Data of Ionized Nebulae},
  journal = {Journal of Open Source Software},
  volume = {4},
  number = {35},
  pages = {898},
  year = {2019},
  doi = {10.21105/joss.00898}
}

and if you use the AtomNeb Python package:

@article{Danehkar2020,
  author = {{Danehkar}, Ashkbiz},
  title = {AtomNeb Python Package, an addendum to AtomNeb: IDL Library
           for Atomic Data of Ionized Nebulae},
  journal = {Journal of Open Source Software},
  volume = {5},
  number = {55},
  pages = {2797},
  year = {2020},
  doi = {10.21105/joss.02797}
}

Learn More

Documentation https://atomneb.github.io/AtomNeb-idl/doc/
Repository https://github.com/atomneb/AtomNeb-idl
Issues & Ideas https://github.com/atomneb/AtomNeb-idl/issues
DOI 10.21105/joss.00898
Archive 10.5281/zenodo.2584419