THEMIS 2.0: A self-consistent model for dust extinction, emission, and polarisation

Ysard, N.; Jones, A. P.; Guillet, V.; Demyk, K.; Decleir, M.; Verstraete, L.; Choubani, I.; Miville-Deschênes, M.-A.; Fanciullo, L.

doi:10.1051/0004-6361/202348391

Cited by 4 publications

(1 citation statement)

References 143 publications

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“…In the present work, we ask whether high-porosity grains are consistent with the observed polarizing properties of interstellar dust. The polarizing efficiency of interstellar dust is observed to be quite high; this strongly constrains the shapes of interstellar dust grains (Rogers & Martin 1979;Kim & Martin 1995;Draine & Fraisse 2009;Fanciullo et al 2017;Draine & Hensley 2021a;Hensley & Draine 2023;Ysard et al 2024). Paper I (Draine 2024) considered a variety of simple convex shapes.…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of Polarization to Grain Shape. II. Aggregates

Draine

2024

ApJ

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A previous study (Paper I) investigated the polarization properties of a variety of simple convex grain shapes, some of which were found to be consistent with the observed polarization properties of interstellar dust from far-ultraviolet to far-infrared. Here, we study the optical properties of 45 nonconvex shapes, all aggregates of N equal-sized spheres. We consider N = 2, N = 3, and N = 256 random aggregates obtained from three different aggregation schemes. We also consider “trimmed” N = 256 aggregates obtained by systematically trimming initially random aggregates to increase either flattening or elongation. The “macroporosities” of the studied aggregates range from P macro = 0.18 (for the N = 2 bisphere) to P macro ≈ 0.85 (for the N = 256 “BA” aggregates). The only aggregates consistent with observations of starlight polarization and polarized thermal emission are shapes that have been trimmed to increase their asymmetry. If interstellar grains are high-porosity aggregates, there must be processes causing extreme elongation or flattening; if not, interstellar grains must be dominated by fairly compact structures, with at most moderate porosities. The ratio of polarization in the 10 μm silicate feature to starlight polarization in the optical is shown to be insensitive to porosity and shape. X-ray scattering may be the best tool to determine the porosity of interstellar grains. We propose that modest porosities of interstellar grains could be the result of “photolytic densification.” High polarization fractions observed in some Class 0 cores require processes to reduce porosities and/or increase asymmetries of aggregates in dense regions.

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Section: Introductionmentioning

confidence: 99%

Sensitivity of Polarization to Grain Shape. II. Aggregates

Draine

2024

ApJ

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General non-linear fragmentation with discontinuous Galerkin methods

Lombart,

Bréhier,

Hutchison

et al. 2024

Monthly Notices of the Royal Astronomical Society

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Dust grains play a significant role in several astrophysical processes, including gas/dust dynamics, chemical reactions, and radiative transfer. Replenishment of small-grain populations is mainly governed by fragmentation during pair-wise collisions between grains. The wide spectrum of fragmentation outcomes, from complete disruption to erosion and/or mass transfer, can be modelled by the general non-linear fragmentation equation. Efficiently solving this equation is crucial for an accurate treatment of the dust fragmentation in numerical modelling. However, similar to dust coagulation, numerical errors in current fragmentation algorithms employed in astrophysics are dominated by the numerical overdiffusion problem – particularly in three-dimensional hydrodynamic simulations where the discrete resolution of the mass-density distribution tends to be highly limited. With this in mind, we have derived the first conservative form of the general non-linear fragmentation with a mass flux highlighting the mass transfer phenomenon. Then, to address cases of limited mass density resolution, we applied a high-order discontinuous Galerkin scheme to efficiently solve the conservative fragmentation equation with a reduced number of dust bins. An accuracy of $0.1{\!-\!}1~{{\ \rm per\ cent}}$ is reached with 20 dust bins spanning a mass range of 9 orders of magnitude.

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dust_extinction: Interstellar Dust Extinction Models

Gordon

2024

JOSS

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THEMIS 2.0: A self-consistent model for dust extinction, emission, and polarisation

Cited by 4 publications

References 143 publications

Sensitivity of Polarization to Grain Shape. II. Aggregates

Sensitivity of Polarization to Grain Shape. II. Aggregates

General non-linear fragmentation with discontinuous Galerkin methods

dust_extinction: Interstellar Dust Extinction Models

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