The effect of photoionization on the cooling rates of enriched, astrophysical plasmas

Wiersma, Robert P. C.; Schaye, Joop; Smith, Britton D.

doi:10.1111/j.1365-2966.2008.14191.x

Cited by 938 publications

(1,008 citation statements)

References 27 publications

Supporting

Mentioning

992

Contrasting

Unclassified

Order By: Relevance

“…Optically thin cooling was implemented using the tables compiled by Wiersma et al (2009) from the code CLOUDY (Ferland et al 1998), assuming solar metallicity. Within the cooling routine, sub-cycling was implemented (Gray & Scannapieco 2010) and we introduced a cooling floor at T = 10 4 K.…”

Section: Methodsmentioning

confidence: 99%

The Launching of Cold Clouds by Galaxy Outflows. Ii. The Role of Thermal Conduction

Brüggen

Scannapieco

2016

ApJ

128

120

View full text Add to dashboard Cite

We explore the impact of electron thermal conduction on the evolution of radiatively cooled cold clouds embedded in flows of hot and fast material as it occurs in outflowing galaxies. Performing a parameter study of threedimensional adaptive mesh refinement hydrodynamical simulations, we show that electron thermal conduction causes cold clouds to evaporate, but it can also extend their lifetimes by compressing them into dense filaments. We distinguish between low column-density clouds, which are disrupted on very short times, and high-column density clouds with much longer disruption times that are set by a balance between impinging thermal energy and evaporation. We provide fits to the cloud lifetimes and velocities that can be used in galaxy-scale simulations of outflows in which the evolution of individual clouds cannot be modeled with the required resolution. Moreover, we show that the clouds are only accelerated to a small fraction of the ambient velocity because compression by evaporation causes the clouds to present a small cross-section to the ambient flow. This means that either magnetic fields must suppress thermal conduction, or that the cold clouds observed in galaxy outflows are not formed of cold material carried out from the galaxy.

show abstract

Section: Methodsmentioning

confidence: 99%

The Launching of Cold Clouds by Galaxy Outflows. Ii. The Role of Thermal Conduction

Brüggen

Scannapieco

2016

ApJ

128

120

View full text Add to dashboard Cite

show abstract

“…It reaches a temperature T > 10 5 K and a density between a hundred and a thousand times the mean density of the universe (Birnboim and Dekel 2003;Kereš et al 2005). Gas at this temperature and density exhibits a cooling time of several Gyr (e.g., Dekel and Birnboim 2006;Wiersma et al 2009), which is long enough for the gas to be spread over the halo by the time it settles down onto the galaxy disk. The high-temperature gas is too tenuous to be observed in X-ray, and is fully ionized.…”

Section: Expected Properties Of Accreted Gasmentioning

confidence: 99%

Star formation sustained by gas accretion

Alméida

Elmegreen

Muñoz–Tuñón

et al. 2014

Astron Astrophys Rev

171

128

View full text Add to dashboard Cite

Numerical simulations predict that metal-poor gas accretion from the cosmic web fuels the formation of disk galaxies. This paper discusses how cosmic gas accretion controls star formation, and summarizes the physical properties expected for the cosmic gas accreted by galaxies. The paper also collects observational evidence for gas accretion sustaining star formation. It reviews evidence inferred from neutral and ionized hydrogen, as well as from stars. A number of properties characterizing large samples of star-forming galaxies can be explained by metal-poor gas accretion, in particular, the relationship among stellar mass, metallicity, and star-formation rate (the so-called fundamental metallicity relationship). They are put forward and analyzed. Theory predicts gas accretion to be particularly important at high redshift, so indications based on distant objects are reviewed, including the global star-formation history of the universe, and the gas around galaxies as inferred from absorption features in the spectra of background sources.

show abstract

“…Their estimated H2 mass does not include the contribution of helium. They considered radiative cooling (Wiersma et al 2009;Schaye et al 2015), photo-heating by cosmic microwave background, UV and X-ray background radiation (Haardt & Madau 2001 (Springel et al 2005b). With the L-GALAXIES, they implemented radiative cooling with the cooling function of Sutherland & Dopita (1993), photoionisation heating (Gnedin 2000;Kravtsov et al 2004), star formation (Kauffmann 1996;Kennicutt 1989), and the feedbacks from SNe and AGN (Croton et al 2006).…”

Section: Galaxy Formation Models In the Literaturesmentioning

confidence: 99%

Redshift evolution of stellar mass versus gas fraction relation in 0 <z< 2 regime: observational constraint for galaxy formation models

Morokuma-Matsui¹,

Baba²

2015

Mon. Not. R. Astron. Soc.

View full text Add to dashboard Cite

We investigate the redshift evolution of the molecular gas mass fraction (f mol = M mol M⋆+M mol , where M mol is molecular gas mass and M ⋆ is stellar mass) of galaxies in the redshift range of 0 < z < 2 as a function of the stellar mass by combining CO literature data. We observe a stellar-mass dependence of the f mol evolution where massive galaxies have largely depleted their molecular gas at z = 1, whereas the f mol value of less massive galaxies drastically decreases from z = 1. We compare the observed M ⋆ −f mol relation with theoretical predictions from cosmological hydrodynamic simulations and semi-analytical models for galaxy formation. Although the theoretical studies approximately reproduce the observed mass dependence of f mol evolution, they tend to underestimate the f mol values, particularly of less massive (< 10 10 M ⊙ ) and massive galaxies (> 10 11 M ⊙ ) when compared with the observational values. Our result suggests the importance of the feedback models which suppress the star formation while simultaneously preserving the molecular gas in order to reproduce the observed M ⋆ − f mol relation.

show abstract

The effect of photoionization on the cooling rates of enriched, astrophysical plasmas

Cited by 938 publications

References 27 publications

The Launching of Cold Clouds by Galaxy Outflows. Ii. The Role of Thermal Conduction

The Launching of Cold Clouds by Galaxy Outflows. Ii. The Role of Thermal Conduction

Star formation sustained by gas accretion

Redshift evolution of stellar mass versus gas fraction relation in 0 <z< 2 regime: observational constraint for galaxy formation models

Contact Info

Product

Resources

About