ROBO: a model and a code for studying the interstellar medium

Krstić, Predrag; Merlin, E.; Buonomo, U.; Piovan, L.; Chiosi, C.

doi:10.1051/0004-6361/200913779

Cited by 28 publications

(37 citation statements)

References 69 publications

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“…To this end, we investigate various choices of the sticking coefficient: (1) a fixed value a = 1 for  T 300 gas K and a = 0 for > T 300 gas K,(2) a fixed value a = 1 for all temperatures,(3) anexperimentally measured α for chemisorption of H 2 molecules on silicate surfaces by Chaabouni et al (2012),and (4) a T T , gas dust ( ) from theoretical calculations of physisorption performed by Leitch-Devlin & Williams (1985). In theabsence of estimates of α for physisorption of Si on silicate grain surfaces, we provisionally adopt the data for carbon atoms arriving on a graphite lattice from the work by Leitch-Devlin & Williams (1985), in the functional form derived by Grassi et al (2011). The dust temperature is fixed to 20K.…”

Section: Sticking Coefficientmentioning

confidence: 99%

Modeling Dust Evolution in Galaxies With a Multiphase, Inhomogeneous Ism

Zhukovska

Dobbs

Jenkins

et al. 2016

ApJ

149

160

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We develop a model of dust evolution in a multiphase, inhomogeneous interstellar medium (ISM) using hydrodynamical simulations of giant molecular clouds in a Milky Way-like spiral galaxy. We improve the treatment of dust growth by accretion in the ISM to investigate the role of the temperature-dependent sticking coefficient and ion-grain interactions. From detailed observational data on the gas-phase Si abundances Si H ] and the local gas density n H ( )thatwe use as a critical constraint for the models. This relation requires a sticking coefficient that decreases with the gas temperature. The relation predicted by the models reproduces the slope of −0.5 forthe observed relation in cold clouds, which is steeper than that for the warm medium and is explained by dust growth. We find that growth occurs in the cold medium for all adopted values of the minimum grain size a min from 1 to 5nm. ] -n H ( ) relation, and provide a better match to observations. The rates of dust re-formation in the ISM by far exceed the rates of dust production by stellar sources. After the initial 140Myr, the cycle of matter in and out of dust reaches a steady state, in which the dust growth balances the destruction on a similar timescale of 350Myr.

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Section: Sticking Coefficientmentioning

confidence: 99%

Modeling Dust Evolution in Galaxies With a Multiphase, Inhomogeneous Ism

Zhukovska

Dobbs

Jenkins

et al. 2016

ApJ

149

160

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“…By using , the typical time‐scale τ () can be estimated as where a 0.1 ≡ a 0 /0.1 μ m, n 3 ≡ n H /10 3 cm −3 , T 50 ≡ T gas /50 K and S 0.3 = S /0.3. Unless otherwise stated, we adopt n H = 10 3 cm −3 and T = 50 K for the typical values derived from observational properties of Galactic molecular clouds (Hirashita 2000a), and S = 0.3 (Leitch‐Devlin & Williams 1985; Grassi et al 2011). Although S may be almost 1 in such low temperature environments as molecular clouds (Zhukovska et al 2008), the chemical factor (i.e.…”

Section: Formulationmentioning

confidence: 99%

Effects of grain size distribution on the interstellar dust mass growth

Hirashita¹,

Kuo²

2011

Monthly Notices of the Royal Astronomical Society

102

158

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Grain growth by the accretion of metals in interstellar clouds (called `grain growth') could be one of the dominant processes that determine the dust content in galaxies. The importance of grain size distribution for the grain growth is demonstrated in this paper. First, we derive an analytical formula that gives the grain size distribution after the grain growth in individual clouds for any initial grain size distribution. The time-scale of the grain growth is very sensitive to grain size distribution, since the grain growth is mainly regulated by the surface to volume ratio of grains. Next, we implement the results of grain growth into dust enrichment models of entire galactic system along with the grain formation and destruction in the interstellar medium, finding that the grain growth in clouds governs the dust content in nearby galaxies unless the grain size is strongly biased to sizes larger than $\sim 0.1 \micron$ or the power index of the grain size distribution is shallower than $\sim -2.5$. The grain growth in clouds contributes to the rapid increase of dust-to-gas ratio at a certain metallicity level (called critical metallicity in Asano et al. 2011 and and Inoue 2011), which we find to be sensitive to grain size distribution. Thus, the grain growth efficiently increase the dust mass not only in nearby galaxies but also in high-redshift quasars, whose metallicities are larger than the critical value. Our recipe for the grain growth is applicable for any grain size distribution and easily implemented into any framework of dust enrichment in galaxies.Comment: 14 pages, 10 figures, accepted for publication in MNRA

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“…Hirashita & Kuo (2011) derive the dust‐growth time‐scale for silicate (a similar time‐scale is obtained for carbonaceous dust): where 〈 a 3 〉 and 〈 a 2 〉 are the averages of a 3 and a 2 ( a is the grain radius) for grain‐size distribution, Z is the metallicity, n H is the hydrogen number density, T gas is the gas temperature and S is the sticking efficiency of the relevant metal species on to the dust surface. We assume Z ⊙ (see Introduction), n H = 10 5 cm −3 (Table 3), T gas = 50 K (Wilson, Walker & Thornley 1997) and S = 0.3 (Leitch‐Devlin & Williams 1985; Grassi et al 2011). Then, we obtain τ grow ∼ 8.4 × 10 5 yr, which is comparable to the star‐formation time‐scale.…”

Section: Contribution From Dust In the Centrementioning

confidence: 99%

Central free-free dominated 880-μm emission in II Zw 40

Hirashita¹

2011

Monthly Notices of the Royal Astronomical Society

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The central star-forming region in a blue compact dwarf galaxy, II Zw 40, was observed in the 340 GHz (880 µm) band at ∼ 5 arcsec (250 pc) resolution with the Submillimetre Array (SMA). A source associated with the central star-forming complex was detected with a flux of 13.6 ± 2.0 mJy. The structure is more extended than the beam in the east-west direction. The SMA 880 µm flux is analyzed by using theoretical models of radio spectral energy distribution along with centimetre interferometric measurements in the literature. We find (i) that the SMA 880 µm flux is dominated (∼ 75 per cent) by free-free emission from the central compact starforming region, and (ii) that the contribution from dust emission to the SMA 880 µm flux is at most 4 ± 2.5 mJy. We also utilize our models to derive the radio-FIR relation of the II Zw 40 centre, suggesting that free-free absorption at low frequencies (ν several GHz; λ several cm) and spatial extent of dust affect the radio-FIR relation.

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ROBO: a model and a code for studying the interstellar medium

Cited by 28 publications

References 69 publications

Modeling Dust Evolution in Galaxies With a Multiphase, Inhomogeneous Ism

Modeling Dust Evolution in Galaxies With a Multiphase, Inhomogeneous Ism

Effects of grain size distribution on the interstellar dust mass growth

Central free-free dominated 880-μm emission in II Zw 40

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