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Your search keyword '"Fischera, Jörg"' showing total 13 results
Start Over Author "Fischera, Jörg" Publication Type Academic Journals
13 results on '"Fischera, Jörg"'

1. Predicting the stellar and non-equilibrium dust emission spectra of high-resolution simulated galaxies with DART-RAY.

Author

Natale, Giovanni, Popescu, Cristina C., Tuffs, Richard. J., Debattista, Victor P., Fischera, Jörg, and Grootes, Meiert W.

Subjects
STELLAR populations, EMISSION spectroscopy, HIGH resolution spectroscopy, GALAXY clusters, RADIATIVE transfer, SPECTRAL energy distribution
Abstract

We describe the calculation of the stochastically heated dust emission using the 3D ray-tracing dust radiative transfer code DART-RAY, which is designed to solve the dust radiative transfer problem for galaxies with arbitrary geometries. In order to reduce the time required to derive the non-equilibrium dust emission spectra from each volume element within a model, we implemented an adaptive spectral energy distribution library approach, which we tested for the case of axisymmetric galaxy geometries. To show the capabilities of the code, we applied DART-RAY to a high-resolution N-body+SPH galaxy simulation to predict the appearance of the simulated galaxy at a set of wavelengths from the UV to the sub-mm. We analyse the results to determine the effect of dust on the observed radial and vertical profiles of the stellar emission as well as on the attenuation and scattering of light from the constituent stellar populations. We also quantify the proportion of dust re-radiated stellar light powered by young and old stellar populations, both bolometrically and as a function of infrared wavelength. [ABSTRACT FROM AUTHOR]

Published
2015
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2. On the probability distribution function of the mass surface density of molecular clouds. II.

Author

Fischera, Jörg

Subjects
*MASS density gradients, *MOLECULAR clouds, *ATMOSPHERIC density, *TURBULENCE, *ASTROPHYSICS
Abstract

The probability distribution function (PDF) of the mass surface density of molecular clouds provides essential information about the structure of molecular cloud gas and condensed structures out of which stars may form. In general, the PDF shows two basic components: a broad distribution around the maximum with resemblance to a log-normal function, and a tail at high mass surface densities attributed to turbulence and self-gravity. In a previous paper, the PDF of condensed structures has been analyzed and an analytical formula presented based on a truncated radial density profile, ρ(r) = ρc/(1 + (r/r0)2)n/2 with central density ρc and inner radius r0, widely used in astrophysics as a generalization of physical density profiles. In this paper, the results are applied to analyze the PDF of self-gravitating, isothermal, pressurized, spherical (Bonnor-Ebert spheres) and cylindrical condensed structures with emphasis on the dependence of the PDF on the external pressure pext and on the overpressure q-1 = pc/pext, where pc is the central pressure. Apart from individual clouds, we also consider ensembles of spheres or cylinders, where effects caused by a variation of pressure ratio, a distribution of condensed cores within a turbulent gas, and (in case of cylinders) a distribution of inclination angles on the mean PDF are analyzed. The probability distribution of pressure ratios q-1 is assumed to be given by P(q-1) ∝ q-k1 /(1 + (q0/q) γ)(k1+k2) /γ , where k1, γ, k2, and q0 are fixed parameters. The PDF of individual spheres with overpressures below ∼100 is well represented by the PDF of a sphere with an analytical density profile with n = 3. At higher pressure ratios, the PDF at mass surface densities ∑ ⪡ ∑(0), where ∑(0) is the central mass surface density, asymptotically approaches the PDF of a sphere with n = 2. Consequently, the power-law asymptote at mass surface densities above the peak steepens from Psph(∑) ∝ ∑ -2 to Psph(∑) ∝ ∑ -3. The corresponding asymptote of the PDF of cylinders for the large q-1 is approximately given by Pcyl(∑) ∝ ∑ -4/3(1-(∑/∑(0))2/3)-½ . The distribution of overpressures q-1 produces a power-law asymptote at high mass surface densities given by {Psph(∑) } ∝ ∑ -2k 2 -1 (spheres) or {Pcyl(∑) } ∝ ∑ -2k 2 (cylinders). [ABSTRACT FROM AUTHOR]

Published
2014
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7. Modeling the dust Spectral Energy Distribution of NGC 4214.

Author

Hermelo, Israel, Lisenfeld, Ute, Relaño, Mónica, Tuffs, Richard J., Popescu, Cristina C., Fischera, Jörg, and Groves, Brent

Abstract

We have carried out a detailed modeling of the dust Spectral Energy Distribution (SED) of the nearby, starbursting dwarf galaxy NGC 4214. A key point of our modeling is that we distinguish the emission from (i) HII regions and their associated photodissociation regions (PDRs) and (ii) diffuse dust. For both components we apply templates from the literature calculated with a realistic geometry and including radiation transfer. The large amount of existing data from the ultraviolet (UV) to the radio allows the direct measurement of most of the input parameters of the models. We achieve a good fit for the total dust SED of NGC 4214. In the present contribution we describe the available data, the data reduction and the determination of the model parameters, whereas a description of the general outline of our work is presented in the contribution of Lisenfeld et al. in this volume. [ABSTRACT FROM PUBLISHER]

Published
2011
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8. Determining the fraction of dust heating from young and old stellar populations with 3D dust radiative transfer.

Author

Natale, Giovanni, Popescu, Cristina C., Tuffs, Richard. J., Debattista, Victor P., Fischera, Jörg, Grootes, Meiert W., and Benvenuti, Piero

Abstract

A major difficulty hampering the accuracy of UV/optical star formation rate tracers is the effect of interstellar dust, absorbing and scattering light produced by both young and old stellar populations (SPs). Although empirically calibrated corrections or energy balance SED fitting are often used for fast de-reddening of galaxy stellar emission, eventually only radiative transfer calculations can provide self-consistent predictions of galaxy model spectra, taking into account important factors such as galaxy inclination, different morphological components, non-local heating of the dust and scattered radiation. In addition, dust radiative transfer can be used to determine the fraction of monochromatic dust emission powered by either young or old SPs. This calculation needs to take into account the different response of the dust grains to the UV and optical radiation field, depending on the grain size and composition. We determined the dust heating fractions, on both global and local scales, for a high-resolution galaxy model by using our 3D ray-tracing dust radiative transfer code “DART-Ray”. We show the results obtained using this method and discuss the consequences for star formation rate indicators. [ABSTRACT FROM PUBLISHER]

Published
2015
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