=====
Grids
=====

The DESK_ downloads and fits both new and commonly-used model grids, automatically.
The grids are also available for download on Zenodo_. Columns are in wavelength (um) and flux density (W*m-2).

DUSTY model grids
-----------------

The DUSTY_ models are 1-D radiative transfer models that exploit
scaling relations to generate models. The model shape can be scaled
to any luminosity, expansion velocity, or mass-loss rate so long as the
combination of these three parameters remains the same. The DESK model grids
contain 2,000--32,000 unique model shapes. Theses grids are scaled
to the desired number of luminosities between 1,000 and 150,000 solar luminosities
using the command option `--n`.

.. code-block:: console

	> desk fit --source='example.csv' --grid='corundum-mix' --n=10

This command will scale the 'corundum-mix' model grid of 3,000 unique model
shapes to luminosities at 1000, 17555, 34111, 50666, 67222, 83777, 100333, 116888,
133444, and 150000 solar luminosities (30,000 models).

The output model parameters of expansion velocity and gas mass-loss rate are
scaled using the relations from `Elitzur & Ivezić 2001`_. The model flux is scaled
using the brightness and distance to the sun, and scaling for the luminosity
which is already in solar luminosities.

Only the default carbon (amorphous-carbon) and oxygen-rich (silicates) model grids
are downloaded during installation. Additional grids are downloaded when selected.
The number of unique models and the file size of each grid are specified next to
the grid names below.

Except where stated otherwise, the models assume a standard `MRN`_ grain size distribution from
0.005 - 0.25 microns. The DUSTY code uses an analytical approximation of the wind density
distribution. This calculation extends to a distance of 10,000 times the inner
radius (density type = 4, within the DUSTY code).


Oxygen-rich DUSTY model grids
=============================

comarcs-oxygen-atmosphere (*N*\ =5; 0.1 MB): The grid is based on oxygen-rich 
atmospheric COMARCS models with effective temperature (2600-3400 K: 100 K interval). 
This model grid assumes no dust. 

silicates (*N*\ =2,000; 3.4 MB): Uses oxygen-rich warm silicates from
`Ossenkopf et al. (1992)`_ and a black body. This grid provides ranges in
effective temperature (2600-3400 K: 200 K interval) inner dust
temperature (600-1200K: 200 K interval) and optical depth (0.1 - 30: 100
spaced logarithmically).

o-def-silicates (*N*\ =2,000; 3.4 MB): Same as the silicates grid but using
oxygen-deficient warm silicates from `Ossenkopf et al. (1992)`_.


corundum-mix (*N*\ =3,000; 5 MB): Same temperature range as the silicates grid
but with with more limited density of optical depths (0.1 - 30: 50 spaced
logarithmically) created for three scenarios of different fractions of warm
silicates and corundum grains from `Begemann et al. (1997)`_. The fractions
included are 70:30, 80:20, 90:10 for the warm silicates:corundum grain ratio.


crystalline-mix (*N*\ =3,000; 5 MB): Same as corundum-mix but with crystalline silicate
grains from from `Jaeger et al. (1994)`_.


draine-mix (*N*\ =3,000; 5 MB): Same as corundum-mix but with astronomical silicate
grains from from `Draine & Lee (1984)`_.


iron-mix (*N*\ =2,960; 5 MB): Same as corundum-mix but with iron grains from
`Henning et al. (1995)`_,.


carbon-mix (*N*\ =3,000; 5 MB): Same as corundum-mix but with amorphous carbon
grains from `Zubko et al. (1996)`_.


silicate-mix (*N*\ =71,435; 127 MB): This grid provides ranges in
effective temperature (2600-3400 K: 200 K interval) inner dust
temperature (600-1200K: 100 K interval) and optical depth (0.1 - 30: 100
spaced linearally). We set 4% iron grains from `Henning et al. (1995)`_, and different
fractions of the oxygen-rich and
oxygen-deficient grains from `Ossenkopf et al. (1992)`_ and crystalline silicates from
`Jaeger et al. (1994)`_. The fractions for each grain type are 0, 16, 24, 38, 42,
56, 64, 80% for the oxygen-rich and oxygen-deficient silicates with the remainder filled with
the crystalline silicates and 4% iron grains.

Explore this model grid using the `interactive notebook`_


galactic-bulge-OH-IR (*N*\ =7,500; 124 MB): The oxygen-rich grid used in for
`Goldman et al. (2025)`_ The grid is based on atmospheric COMARCS models with effective
temperature (2600-3400 K: 200 K interval) inner dust temperature (600-1200K: 100 K interval)
and optical depth (0.1 - 30: 100 spaced linearally) and optical depth (0.1 - 50: 50 spaced linearally).
The models use a grain composition of 4% metalic iron (`Ordal et al. 1988`_) and fractions of armorphous
and crystalline silicates. The crystalline fraction is set to 1, 3, 6, 10, or 15%, with the remaining
fraction filled with amorphous silicates. These models are the full hydrodynamical solution for the
density structure of the wind.


galactic-bulge-OH-IR-mmrn (*N*\ =7,500; 124 MB): Same as galactic-bulge-OH-IR but with a MRN grain size
distribution with a larger maximum allowable grain size of 0.5 micron.


Carbon-rich DUSTY model grids
=============================

comarcs-carbon-atmosphere (*N*\ =7; 0.1 MB): The grid is based on carbon-rich 
atmospheric COMARCS models with effective temperature (2400-3400 K: 100 K interval). 
This model grid assumes no dust. 

amorphous-carbon (*N*\ =1,340; 145 MB): Same as silicates but with
amorphous carbon grains from `Zubko et al. (1996)`_.


.. _the-dust-growth-model-grids-from-nanni-et-al-2019:

Dust growth grids
=================

The dust growth model grids from `Nanni et al. (2019)`_.

H11-LMC (*N*\ =90,899; 770 MB): A carbon-rich grid for the LMC metallicity (1/2
solar) using optical constants from `Hanner et al. (1988)`_.

H11-SMC (*N*\ =91,058; 772 MB): A carbon-rich grid for the SMC metallicity (1/5
solar) using optical constants from `Hanner et al. (1988)`_.

J1000-LMC (*N*\ =85,392; 723 MB): A carbon-rich grid for the LMC metallicity
(1/2 solar) using optical constants from `Jaeger et al. (1998)`_

J1000-SMC (*N*\ =85,546; 724 MB): A carbon-rich grid for the SMC metallicity
(1/5 solar) using optical constants from `Jaeger et al. (1998)`_


2-D model grids
-------------------------


The GRAMS model grids
=====================

The GRAMS model grids from `Sargent et al. (2011)`_ and `Srinivasan et al. (2011)`_.
These models assume a density distribution of 1/r\ :sup:`2`, a modified KMH dust grain
distribution, and an assumed expansion velocity of 10 km/s. Compared to the 1D DUSTY models,
the optical depths for the GRAMS models are more limited, with  optical depths at 10 microns
ranging from 0.001-0.4 for the carbon-rich grid, to 0.0001-26 for the oxygen-rich grid.


grams-carbon (*N*\ =12,244; 41.3 MB): A 2D carbon-rich grid using the `2DUST`_
code for the LMC metallicity (1/2 solar) using optical constants from
`Zubko et al. (1996)`_.

grams-oxygen (*N*\ =68,601; 200 MB): A 2D oxygen-rich grid using the `2DUST`_
code for the LMC metallicity (1/2 solar) using optical constants from
`Ossenkopf et al. (1992)`_.

grams: Both GRAMS datasets combined

.. code:: diff

   - Warning: results uncertain outside of a distance 20-150 kpc.

.. _DESK: https://github.com/s-goldman/Dusty-Evolved-Star-Kit
.. _Zenodo: https://doi.org/10.5281/zenodo.14448621
.. _DUSTY: https://github.com/ivezic/dusty
.. _Elitzur & Ivezić 2001: https://ui.adsabs.harvard.edu/abs/2001MNRAS.327..403E/abstract
.. _Sargent et al. (2011): https://ui.adsabs.harvard.edu/abs/2011ApJ...728...93S/abstract
.. _Srinivasan et al. (2011): https://ui.adsabs.harvard.edu/abs/2011A%26A...532A..54S/abstract
.. _2DUST: https://ui.adsabs.harvard.edu/abs/2003ApJ...586.1338U/abstract
.. _Zubko et al. (1996): https://ui.adsabs.harvard.edu/abs/1996MNRAS.282.1321Z/abstract
.. _Ossenkopf et al. (1992): https://ui.adsabs.harvard.edu/abs/1992A%26A...261..567O/abstract
.. _Aringer et al. (2016): https://ui.adsabs.harvard.edu/abs/2016MNRAS.457.3611A/abstract
.. _MRN: https://ui.adsabs.harvard.edu/abs/1977ApJ...217..425M/abstract
.. _Jaeger et al. (1994): https://ui.adsabs.harvard.edu/abs/1994A%26A...292..641J/abstract
.. _Jaeger et al. (1998): https://ui.adsabs.harvard.edu/abs/1998A%26A...339..904J/abstract
.. _Begemann et al. (1997): https://ui.adsabs.harvard.edu/abs/1997ApJ...476..199B/abstract
.. _Henning et al. (1995): https://ui.adsabs.harvard.edu/abs/1995A%26AS..112..143H/abstract
.. _Zubko et al. (1996): https://ui.adsabs.harvard.edu/abs/1996MNRAS.282.1321Z/abstract
.. _Nanni et al. (2019): https://ui.adsabs.harvard.edu/abs/2019MNRAS.487..502N/abstract
.. _Hanner et al. (1988): https://ui.adsabs.harvard.edu/abs/1988ioch.rept.....H/abstract
.. _Groenewegen 2012: https://ui.adsabs.harvard.edu/abs/2012A&A...543A..36G/abstract
.. _Dorschner et al. (1995): https://ui.adsabs.harvard.edu/abs/1995A&A...300..503D/abstract
.. _Gustafsson et al. (2008): https://ui.adsabs.harvard.edu/abs/2008A%26A...486..951G/abstract
.. _Draine & Lee (1984): https://ui.adsabs.harvard.edu/abs/1984ApJ...285...89D/abstract
.. _interactive notebook: https://mybinder.org/v2/gh/s-goldman/Dusty-Evolved-Star-Kit_notebooks/main?labpath=silicate-mix_interactive.ipynb
.. _Goldman et al. (2025): https://arxiv.org/abs/2501.02722
.. _Ordal et al. 1988: https://ui.adsabs.harvard.edu/abs/1988ApOpt..27.1203O/abstract