Your search keyword '"Acharyya, Ayan"' showing total 2 results

1. KODIAQ-Z: Metals and Baryons in the Cool Intergalactic and Circumgalactic Gas at 2.2 ≲ z ≲ 3.6.

Author

Lehner, Nicolas, Kopenhafer, Claire, O’Meara, John M., Howk, J. Christopher, Fumagalli, Michele, Prochaska, J. Xavier, Acharyya, Ayan, O’Shea, Brian W., Peeples, Molly S., Tumlinson, Jason, and Hummels, Cameron B.

Subjects

BARYONS, INTERSTELLAR medium, METALS, GASES, COLUMNS

Abstract

We present the KODIAQ-Z survey aimed to characterize the cool, photoionized gas at 2.2 ≲ z ≲ 3.6 in 202 H i -selected absorbers with 14.6 ≤ log N H I < 20 that probe the interface between galaxies and the intergalactic medium (IGM). We find that gas with 14.6 ≤ log N H I < 20 at 2.2 ≲ z ≲ 3.6 can be metal-rich (âˆ'1.6 ≲ [X/H] ≲ âˆ' 0.2) as seen in damped Ly α absorbers (DLAs); it can also be very metal-poor ([X/H] < âˆ' 2.4) or even pristine ([X/H] < âˆ' 3.8), which is not observed in DLAs but is common in the IGM. For 16 < log N H I < 20 absorbers, the frequency of pristine absorbers is about 1%â€"10%, while for 14.6 ≤ log N H I ≤ 16 absorbers it is 10%â€"20%, similar to the diffuse IGM. Supersolar gas is extremely rare (<1%) at these redshifts. The factor of several thousand spread from the lowest to highest metallicities and large metallicity variations (a factor of a few to >100) between absorbers separated by less than Î" v < 500 km sâˆ'1 imply that the metals are poorly mixed in 14.6 ≤ log N H I < 20 gas. We show that these photoionized absorbers contribute to about 14% of the cosmic baryons and 45% of the cosmic metals at 2.2 ≲ z ≲ 3.6. We find that the mean metallicity increases with N H i , consistent with what is found in z < 1 gas. The metallicity of gas in this column density regime has increased by a factor ∼8 from 2.2 ≲ z ≲ 3.6 to z < 1, but the contribution of the 14.6 ≤ log N H I < 19 absorbers to the total metal budget of the universe at z < 1 is a quarter of that at 2.2 ≲ z ≲ 3.6. We show that FOGGIE cosmological zoom-in simulations have a similar evolution of [X/H] with N H i , which is not observed in lower-resolution simulations. In these simulations, very metal-poor absorbers with [X/H] < âˆ' 2.4 at z ∼ 2â€"3 are tracers of inflows, while higher-metallicity absorbers are a mixture of inflows and outflows. [ABSTRACT FROM AUTHOR]

Published

2022

2. Spatial Variation in Strong Line Ratios and Physical Conditions in Two Strongly Lensed Galaxies at z ∼ 1.4.

Author

Florian, Michael K., Rigby, Jane R., Acharyya, Ayan, Sharon, Keren, Gladders, Michael D., Kewley, Lisa, Khullar, Gourav, Gozman, Katya, Brammer, Gabriel, Momcheva, Ivelina, Nicholls, David, LaMassa, Stephanie, Dahle, Håkon, Bayliss, Matthew B., Wuyts, Eva, Johnson, Traci, and Whitaker, Katherine

Subjects

SPATIAL variation, GALAXIES, STAR formation, SPACE telescopes, INFRARED cameras

Abstract

Upcoming space-based integral field spectrographs will enable spatially resolved spectroscopy of distant galaxies, including at the scale of individual star-forming regions (i.e., down to just tens of parsecs) in galaxies that have been strongly gravitationally lensed. In the meantime, there is only a very small set of lensed galaxies where such spatial detail is possible at wavelengths containing important rest-optical emission lines, even with the Hubble Space Telescope's Wide Field Camera 3 infrared channel grisms. Here, we examine two of these sources, SDSS J1723+3411 and SDSS J2340+2947, using HST WFC3/IR grism data and supporting spatially unresolved spectroscopy from several ground-based instruments to explore the size of spatial variations in observed strong emission-line ratios like O32 and R23, which are sensitive to ionization parameter and metallicity, and the Balmer decrement, which is an indicator of reddening. We find significant spatial variation in the reddening and in the reddening-corrected O32 and R23 values that correspond to spreads of a few tenths of a dex in ionization parameter and metallicity. We also find clear evidence of a negative radial gradient in star formation in SDSS J2340+2947 and tentative evidence of one in SDSS J1723+3411, though its star formation is quite asymmetric. Finally, we find that reddening can vary enough spatially to make spatially resolved reddening corrections necessary in order to characterize gradients in line ratios and the physical conditions inferred from them, necessitating the use of space-based integral field units for future work on larger, more statistically robust samples. [ABSTRACT FROM AUTHOR]

Published

2021