LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths

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LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths. / Brinch, Christian; Hogerheijde, Michiel.

In: Astronomy & Astrophysics, Vol. 523, A25, 11.11.2010.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Brinch, C & Hogerheijde, M 2010, 'LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths', Astronomy & Astrophysics, vol. 523, A25. < http://dx.doi.org/10.1051/0004-6361/201015333>

APA

Brinch, C., & Hogerheijde, M. (2010). LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths. Astronomy & Astrophysics, 523, [A25]. http://dx.doi.org/10.1051/0004-6361/201015333

Vancouver

Brinch C, Hogerheijde M. LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths. Astronomy & Astrophysics. 2010 Nov 11;523. A25.

Author

Brinch, Christian ; Hogerheijde, Michiel. / LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths. In: Astronomy & Astrophysics. 2010 ; Vol. 523.

Bibtex

@article{58cc3f2b03054e428ebabadb49f5d8b5,
title = "LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths",
abstract = "We present a new code for solving the molecular and atomic excitation and radiation transfer problem in a molecular gas and predicting emergent spectra. This code works in arbitrary three dimensional geometry using unstructured Delaunay latices for the transport of photons. Various physical models can be used as input, ranging from analytical descriptions over tabulated models to SPH simulations. To generate the Delaunay grid we sample the input model randomly, but weigh the sample probability with the molecular density and other parameters, and thereby we obtain an average grid point separation that scales with the local opacity. Our code does photon very efficiently so that the slow convergence of opaque models becomes traceable. When convergence between the level populations, the radiation field, and the point separation has been obtained, the grid is ray-traced to produced images that can readily be compared to observations. Because of the high dynamic range in scales that can be resolved using this type of grid, our code is particularly well suited for modeling of ALMA data. Our code can furthermore deal with overlapping lines of multiple molecular and atomic species.",
author = "Christian Brinch and Michiel Hogerheijde",
year = "2010",
month = nov,
day = "11",
language = "English",
volume = "523",
journal = "Astronomy & Astrophysics",
issn = "0004-6361",
publisher = "E D P Sciences",

}

RIS

TY - JOUR

T1 - LIME - a flexible, non-LTE line excitation and radiation transfer method for millimeter and far-infrared wavelengths

AU - Brinch, Christian

AU - Hogerheijde, Michiel

PY - 2010/11/11

Y1 - 2010/11/11

N2 - We present a new code for solving the molecular and atomic excitation and radiation transfer problem in a molecular gas and predicting emergent spectra. This code works in arbitrary three dimensional geometry using unstructured Delaunay latices for the transport of photons. Various physical models can be used as input, ranging from analytical descriptions over tabulated models to SPH simulations. To generate the Delaunay grid we sample the input model randomly, but weigh the sample probability with the molecular density and other parameters, and thereby we obtain an average grid point separation that scales with the local opacity. Our code does photon very efficiently so that the slow convergence of opaque models becomes traceable. When convergence between the level populations, the radiation field, and the point separation has been obtained, the grid is ray-traced to produced images that can readily be compared to observations. Because of the high dynamic range in scales that can be resolved using this type of grid, our code is particularly well suited for modeling of ALMA data. Our code can furthermore deal with overlapping lines of multiple molecular and atomic species.

AB - We present a new code for solving the molecular and atomic excitation and radiation transfer problem in a molecular gas and predicting emergent spectra. This code works in arbitrary three dimensional geometry using unstructured Delaunay latices for the transport of photons. Various physical models can be used as input, ranging from analytical descriptions over tabulated models to SPH simulations. To generate the Delaunay grid we sample the input model randomly, but weigh the sample probability with the molecular density and other parameters, and thereby we obtain an average grid point separation that scales with the local opacity. Our code does photon very efficiently so that the slow convergence of opaque models becomes traceable. When convergence between the level populations, the radiation field, and the point separation has been obtained, the grid is ray-traced to produced images that can readily be compared to observations. Because of the high dynamic range in scales that can be resolved using this type of grid, our code is particularly well suited for modeling of ALMA data. Our code can furthermore deal with overlapping lines of multiple molecular and atomic species.

M3 - Journal article

VL - 523

JO - Astronomy & Astrophysics

JF - Astronomy & Astrophysics

SN - 0004-6361

M1 - A25

ER -

ID: 99339520