Day 1556

Friday.

1904.10965
Astrometric requirements for strong lensing time-delay cosmography
BIrrer, Treu

The time delay between the arrival of photons of multiple images of time variable sources can be used to constrain absolute distances in the Universe (Refsdal 1964), and in turn obtain a direct estimate of the Hubble constant and other cosmological parameters. To convert the time delay into distances, it is well known that the gravitational potential of the main deflector and the contribution of the matter along the line-of-sight need to be known to a sufficient level of precision. In this paper, we discuss a new astrometric requirement that is becoming important as time-delay cosmography improves in precision and accuracy with larger samples, and better data and modelling techniques. We derive an analytic expression for the propagation of astrometric uncertainties on the multiple image positions into the inference of the Hubble constant and derive requirements depending on image separation and relative time delay. We note that this requirement applies equally to the image position measurements and to the accuracy of the model in reproducing them. To illustrate the requirement, we discuss some example lensing configurations and highlight that, especially for time delays of order 10 days or shorter, the relative astrometric requirement is of order milli-arcseconds. With current optical infrared technology, astrometric uncertainties may be the dominant limitation for strong lensing cosmography in the small image-separation regime.

1904.10972

The X-ray halo scaling relations of supermassive black holes

Gaspari, et al

We study the correlations between (direct) masses of supermassive black holes (SMBHs) and X-ray hot halo properties, by using a Bayesian analysis of archival datasets and theoretical models. We analyze fundamental and composite X-ray variables (plasma temperature, luminosity, density, pressure, and gas/total masses) from galactic to cluster scales. We show novel key scalings, with the tightest relation being the $M_\bullet - T_{\rm x}$, followed by $M_\bullet - L_{\rm x}$ (scatter 0.2-0.3 dex). The tighter scatter and larger correlation coefficient of the X-ray halo scalings compared with the optical counterparts (including the $M_\bullet-\sigma_\ast$), together with the multivariate analysis, suggest that the plasma atmospheres play a more central role than the stellar component in the growth of SMBHs (and ultramassive BHs), in particular accounting for the group/cluster core halo. The derived gas mass scalings also correlate better with $M_\bullet$ than dark matter mass. We provide key insights on environmental features, relic galaxies, and coronae. The comparison of the optical and X-ray fundamental planes shows that, while stars can be described mainly via the virial theorem, X-ray halos are better described by univariate scalings with deviations from self-similar collapse due to feedback processes. We test 3 major channels for BH growth: hot gas accretion, chaotic cold accretion (CCA), and hierarchical BH mergers. Hot/Bondi-like models are ruled out by the data, showing inconsistent anti-correlation with X-ray halos and too low feeding. Cosmological simulations show that binary SMBH mergers are a sub-dominant channel over most of the cosmic time and too rare to induce a central-limit-theorem effect. The scalings are consistent with the predictions of CCA, the rain of matter condensing out of the turbulent X-ray halos, sustaining a self-regulated feedback loop throughout cosmic time.

1904.10992

Half-mass radii for ~7,000 galaxies at 1.0<z<2.5: most of the evolution in the mass-die relation is due to color gradients

Suess, et al

Radial mass-to-light ratio gradients cause the half-mass and half-light radii of galaxies to differ, potentially biasing studies that use half-light radii. Here we present the largest catalog to date of galaxy half-mass radii at z > 1: 7,006 galaxies in the CANDELS fields at 1.0 < z < 2.5. The sample includes both star-forming and quiescent galaxies with stellar masses 9.0 < log(M_* / M_\odot) < 11.5. We test three methods for calculating half-mass radii from multi-band PSF-matched HST imaging: two based on spatially-resolved SED modeling, and one that uses a rest-frame color profile. All three methods agree, with scatter <~0.3 dex. In agreement with previous studies, most galaxies in our sample have negative color gradients (the centers are redder than the outskirts, and r_e,mass < r_e,light). We find that color gradient strength has significant trends with increasing stellar mass, half-light radius, U-V color, and stellar mass surface density. These trends have not been seen before at z>1. Furthermore, color gradients of star-forming and quiescent galaxies show a similar redshift evolution: they are flat at z>~2, then steeply decrease as redshift decreases. This affects the galaxy mass-size relation. The normalizations of the star-forming and quiescent r_mass-M_* relations are 10-40% smaller than the corresponding r_light-M_* relations; the slopes are ~0.1-0.3 dex shallower. Finally, the half-mass radii of star-forming and quiescent galaxies at M_* = 10^{10.5}M_\odot only grow by ~1%$ and ~8% between z~2.25 and z~1.25. This is significantly less than the ~37% and ~47% size increases found when using the half-light radius.

1904.10994

The life cycle of dust

Sadavoy, et al

Dust offers a unique probe of the interstellar medium (ISM) across multiple size, density, and temperature scales. Dust is detected in outflows of evolved stars, star-forming molecular clouds, planet-forming disks, and even in galaxies at the dawn of the Universe. These grains also have a profound effect on various astrophysical phenomena from thermal balance and extinction in galaxies to the building blocks for planets, and changes in dust grain properties will affect all of these phenomena. A full understanding of dust in all of its forms and stages requires a multi-disciplinary investigation of the dust life cycle. Such an investigation can be achieved with a statistical study of dust properties across stellar evolution, star and planet formation, and redshift. Current and future instrumentation will enable this investigation through fast and sensitive observations in dust continuum, polarization, and spectroscopy from near-infrared to millimeter wavelengths.

1904.11014

The nature of ionized gas in the Milky Way galactic fountain

Werk, et al

We address the spatial scale, ionization structure and metal content of gas at the Milky Way disk-halo interface detected as absorption in the foreground of seven halo blue horizontal branch stars (BHBs). The closely-spaced, high-latitude BHB sightlines reach to different heights above the disk, ranging from z = 3 - 14 kpc in the direction of the Northern Galactic Pole. With our high-resolution, S/N > 14, HST/COS and Keck/HIRES spectra, we constrain the distances, velocities, sizes, and carbon content of infalling, intermediate-velocity gaseous structures (IV gas; -90 < v_LSR [km s^-1] < -25 ). We detect transitions that trace multiple ionization states (e.g. CaII, FeII, SiIV, CIV) with column densities that remain constant with height from the disk, indicating that the gas most likely lies within z < 3.4 kpc. The intermediate ionization state gas traced by CIV and SiIV is strongly correlated over the full range of transverse separations probed by our sightlines, indicating large, coherent structures greater than 500 pc in size. The low ionization state material traced by CaII and FeII neither exhibits a correlation with N_HI nor transverse separation, implying cloudlets or clumpiness on scales less than 10 pc. We find that the observed ratio log(N_SiIV/ N_CIV), with a median value of -0.69+/-0.04, is sensitive to the total carbon content of the ionized gas under the assumption of either photoionization or collisional ionization. Our data directly support a physical scenario in which the Milky Way is fed by complex, multiphase processes at its disk-halo interface that involve kpc-scale ionized envelopes or streams containing pc-scale, cool clumps. 

1904.11070

RascalC: a Jackknife approach to estimating single and multi-tracer galaxy covariance matrices

Philcox, et al

To make use of clustering statistics from large cosmological surveys, accurate and precise covariance matrices are needed. We present a new code to estimate large scale galaxy correlation function covariances in arbitrary survey geometries that produces results comparable to a suite of $10^6$ mocks in $\sim 100$ CPU-hours, orders-of-magnitude faster than pre-existing codes. As in previous works, non-Gaussianity is encapsulated via a shot-noise rescaling, with calibrations performed by comparing models to jackknifed survey data. The approach requires data from only a single dataset (without an input correlation function model), and the deviations between large scale model covariances from a mock survey and those from a large suite of mocks are found to be be indistinguishable from noise. In addition, the choice of input mock are shown to be irrelevant for desired noise levels below $\sim 10^5$ mocks. Coupled with its generalization to multi-tracer data-sets, this shows the algorithm to be an excellent tool for analysis, reducing the need for large numbers of mock simulations to be computed.

1904.11185

Dust production scenarios in galaxies at z~6-8.3

Lesniewska, Michalowski

The mechanism of dust formation in galaxies at high redshift is still unknown. Asymptotic giant branch (AGB) stars and explosions of supernovae (SNe) are possible dust producers, and non-stellar processes may substantially contribute to dust production, for example grain growth in the interstellar medium (ISM). Our aim is to determine the contribution to dust production of AGB stars and SNe in nine galaxies at z ~ 6-8.3, for which observations of dust have been recently attempted. In order to determine the origin of the observed dust we have determined dust yields per AGB star and SN required to explain the total amounts of dust in these galaxies. We find that AGB stars were not able to produce the amounts of dust observed in the galaxies in our sample. In order to explain these dust masses, SNe would have to have maximum efficiency and not destroy the dust which they formed. Therefore, the observed amounts of dust in the galaxies in the early universe were formed either by efficient supernovae or by a non-stellar mechanism, for instance the grain growth in the interstellar medium.