1906.11842
Quiescent galaxies at $z \gtrsim 2.5$: observations vs. models
Cecchi, et al
The presence of massive quiescent galaxies at high redshifts is still a challenge for most models of galaxy formation. The aim of this work is to compare the observed number density and properties of these galaxies with the predictions of state-of-the-art models. The sample of massive quiescent galaxies has been selected from the COSMOS2015 photometric catalogue with $z_{\rm phot}\geq 2.5$, $\log (M_*/M_\odot)\geq 10.5$ and $\log(\mathrm{sSFR\,[yr^{-1}]})\le -11$. The photometric SEDs of the selected galaxies have been thoroughly analyzed based on different stellar population synthesis models. The final sample includes only those galaxies qualified as quiescent in all SED fitting runs. The observed properties have been compared to theoretical models: the number density of quiescent galaxies with $10.5 \leq \log(M_*/M_\odot) < 10.8$ is reproduced by some models, although there is a large scatter in their predictions. Instead, very massive $\log(M_{*}/M_{\odot}) \geq 10.8$ are underpredicted by most of the current models of galaxy formation: some of them, built on the CARNage simulation, are consistent with data up to $z \sim 4$, while at higher redshifts the volume of the considered simulation is too small to find such rare objects. Simulated galaxies which match the observed properties in the $\mathrm{sSFR}-M_*$ plane at $z\sim 3$ have been analyzed by reconstructing their evolutionary paths: their merger trees suggest that AGN feedback could be the key process allowing for a rapid quenching of the star formation at $z\gtrsim 4$ and that its treatment should be improved in models.
Quiescent galaxies at $z \gtrsim 2.5$: observations vs. models
Cecchi, et al
The presence of massive quiescent galaxies at high redshifts is still a challenge for most models of galaxy formation. The aim of this work is to compare the observed number density and properties of these galaxies with the predictions of state-of-the-art models. The sample of massive quiescent galaxies has been selected from the COSMOS2015 photometric catalogue with $z_{\rm phot}\geq 2.5$, $\log (M_*/M_\odot)\geq 10.5$ and $\log(\mathrm{sSFR\,[yr^{-1}]})\le -11$. The photometric SEDs of the selected galaxies have been thoroughly analyzed based on different stellar population synthesis models. The final sample includes only those galaxies qualified as quiescent in all SED fitting runs. The observed properties have been compared to theoretical models: the number density of quiescent galaxies with $10.5 \leq \log(M_*/M_\odot) < 10.8$ is reproduced by some models, although there is a large scatter in their predictions. Instead, very massive $\log(M_{*}/M_{\odot}) \geq 10.8$ are underpredicted by most of the current models of galaxy formation: some of them, built on the CARNage simulation, are consistent with data up to $z \sim 4$, while at higher redshifts the volume of the considered simulation is too small to find such rare objects. Simulated galaxies which match the observed properties in the $\mathrm{sSFR}-M_*$ plane at $z\sim 3$ have been analyzed by reconstructing their evolutionary paths: their merger trees suggest that AGN feedback could be the key process allowing for a rapid quenching of the star formation at $z\gtrsim 4$ and that its treatment should be improved in models.
1906.11936
Prospects for memory detection with low-frequency gravitational wave detectors
Islo, et al
Gravitational wave memory is theorized to arise from the integrated history of gravitational wave emission, and manifests as a spacetime deformation in the wake of a propagating gravitational wave. We explore the detectability of the memory signals from a population of coalescencing supermassive black hole binaries with pulsar timing arrays and the Laser Interferometer Space Antenna (LISA). We find that current pulsar timing arrays have poor prospects, but it is likely that between 1 and 10 memory events with signal-to-noise ratio in excess of 5 will occur within LISA's planned 4-year mission.
1906.12060
Delayed spin-up and persistent shift phenomena of Crab pulsar glitches: two sides of the same coin?
Wang, Zheng
Pulsar glitches are sudden increase in their spin frequency, in most cases followed by the long timescale recovery process. As of this writing, about 546 glitches have been reported in 188 pulsars, the Crab pulsar is a special one with unique manifestations. This writing presents a statistic study on post-glitch observables of the Crab pulsar, especially the delayed spin-up in post-glitch phase and persistent shift in the slow-down rate of the star. By analyzing the radio data over 45 years, we find that two power law functions respectively fit the persistent shift and delayed spin-up timescales versus glitch size well, and we find a linear correlation between the persistent shift and delayed spin-up timescale from the consistency of the two fitting functions, probably indicating their same physical origin and may provide a new probe of interior physics of neutron stars.
1906.12308
The partial ionization zone of heavy elements in F-stars: a study on how it correlates with rotation
Brito, Lopes
We study the relation between the internal structures of 10 benchmark main-sequence F-stars and their rotational properties. Stellar rotation of main-sequence F-type stars can be characterised by two distinct rotational regimes. Early-type F-stars are usually rapid rotators with periods typically below 10 days, whereas later-type F-stars have longer rotation periods. Specifically, and since the two rotational regimes are tightly connected to the effective temperatures of the stars, we investigate in detail the characteristics of the partial ionisation zones in the outer convective envelopes of these stars, which in turn, depend on the internal temperature profiles. Our study shows that the two rotational regimes might be distinguished by the relative locations of the partial ionisation region of heavy elements and the base of the convective zone. Since in all these stars is expected a dynamo-driven magnetic field where the shear layer between convective and radiative zones (tachocline) plays an important role, this result suggests that the magnetic field may be related to the combined properties of convection and ionisation.
1906.12347
Consistency of the local Hubble constant with the cosmic microwave background
Lombriser
A significant tension has become manifest between the current expansion rate of our Universe measured from the cosmic microwave background by the Planck satellite and from local distance probes, which has prompted for interpretations of that as evidence of new physics. Within conventional cosmology a likely source of this discrepancy is identified here as a matter density fluctuation around the cosmic average of the 40 Mpc environment in which the calibration of Supernovae Type Ia separations with Cepheids and nearby absolute distance anchors is performed. Inhomogeneities on this scale easily reach 40% and more. In that context, the discrepant expansion rates serve as evidence of residing in an underdense region of $\delta_{\rm env}\approx-0.5\pm0.1$. The probability for finding this local expansion rate given the Planck data lies at the 95% confidence level. Likewise, a hypothetical equivalent local data set with mean expansion rate equal to that of Planck would not gain strong preference over the actual data in the respective Bayes factor. These results therefore suggest consistency between the local and Planck measurements of the Hubble constant. Generally accounting for the environmental uncertainty, the local measurement may be reinterpreted as a constraint on the cosmological Hubble constant of $H_0=(76.5\pm5.5)$ km/s/Mpc for the mean and standard deviation or $H_0=74.7^{+5.8}_{-4.2}$ km/s/Mpc in terms of median and 68% confidence bounds. The current simplified analysis may be augmented with the employment of the full available data sets, an impact study for the immediate $\lesssim10$ Mpc environment of the distance anchors, more prone to inhomogeneities, as well as expansion rates measured by gravitational waves, currently limited to the same 40 Mpc region, and local galaxy motions.
1907.00043
The reconstructed power spectrum in the Zeldovich approximation
Chen, Vlah, White
Density-reconstruction sharpens the baryon acoustic oscillations signal by undoing some of the smoothing incurred by nonlinear structure formation. In this paper we present an analytical model for reconstruction based on the Zeldovich approximation, which for the first time includes a complete set of counterterms and bias terms up to quadratic order and can fit real and redshift-space data pre- and post-reconstruction data in both Fourier and configuration space over a wide range of scales. We compare our model to n-body data at $z = 0$ from the {\tt DarkSky} simulation \cite{skillman14}, finding sub-percent agreement in both real space and in the redshift-space power spectrum monopole out to $k = 0.4\ h$ Mpc$^{-1}$, and out to $k = 0.2\ h$ Mpc$^{-1}$ in the quadrupole, with comparable agreement in configuration space. We compare our model with several popular existing alternatives, updating existing theoretical results for exponential damping in wiggle/no-wiggle splits of the BAO signal and discuss the usually-ignored effect of higher bias contributions on the reconstructed signal. In the appendices, we re-derive the former within our formalism, present exploratory results on higher-order corrections due to nonlinearities inherent to reconstruction, and present numerical techniques with which to calculate the redshift-space power spectrum of biased tracers within the Zeldovich approximation.
1907.00071
A new estimator for gravitational lensing using galaxy and intensity mapping surveys
Jalilvand, et al
We propose a new tomographic estimator for the gravitational lensing potential, based on a combination of intensity mapping (IM) and galaxy counts. The estimator can be written schematically as IM$\times$galaxy $-$ galaxy$\times$IM; this combination allows to greatly reduce the contamination by density-density correlations, thus isolating the lensing signal. We show that the new estimator improves the signal-to-noise ratio for the detection of lensing especially on linear scales and intermediate redshifts. This makes it particularly valuable for future studies of dark energy and modified gravity. For cosmic variance dominated surveys the signal-to-noise ratio is improved by a factor of around 20-30 on linear scales ($\ell_{\rm max}=200$), with a lower improvement of around 5-10 if one includes smaller scales ($\ell_{\rm max}=1000$). Shot noise and interferometer noise reduce the relative improvement to about 1.5-2 for the specific examples of DES and Euclid cross-correlated with HIRAX. Our estimator is additionally less susceptible to systematic effects as it only involves cross-correlations.
The kinematic Sunyaev-Zel'dovich effect enables us to directly probe the density-weighted velocity field up to very large cosmic scales. We investigate the effects of intrinsic alignments (IA) of dark-matter halo shapes on cosmic density and velocity fields on such large scales. In literature IA have been detected up to $\sim 100~h^{-1}{\rm Mpc}$ using the gravitational shear-intrinsic ellipticity (GI) correlation and the alignment correlation function. In this paper we introduce the corresponding various velocity statistics: the (density-weighted) velocity-intrinsic ellipticity (VI) correlation as well as the alignment pairwise infall momentum, momentum correlation function, and density-weighted pairwise velocity dispersion. We derive theoretical expressions for these velocity alignment statistics for the first time based on the assumption that the density fluctuation is a Gaussian random field. Using large-volume, high-resolution $N$-body simulations, we measure the alignment statistics of density and velocity fields. Behaviors of IA in the velocity statistics are similar to those in the density statistics, except that the halo orientations are aligned with the velocity field up to scales larger than those with the density field, $r\gg 100~h^{-1}{\rm Mpc}$, because of a factor of the wavenumber in the linear relation between the density and velocity fields in Fourier space, $v\propto \delta/k$. We show that the detected IA of the velocity field can be well predicted by the linear alignment model. We also demonstrate that the baryon acoustic oscillation features can be detected in both the conventional and alignment velocity statistics. Our results indicate that observations of IA with the velocity field on large scales can provide additional information on cosmological models, complementary to those with the density field.
1907.00071
A new estimator for gravitational lensing using galaxy and intensity mapping surveys
Jalilvand, et al
We propose a new tomographic estimator for the gravitational lensing potential, based on a combination of intensity mapping (IM) and galaxy counts. The estimator can be written schematically as IM$\times$galaxy $-$ galaxy$\times$IM; this combination allows to greatly reduce the contamination by density-density correlations, thus isolating the lensing signal. We show that the new estimator improves the signal-to-noise ratio for the detection of lensing especially on linear scales and intermediate redshifts. This makes it particularly valuable for future studies of dark energy and modified gravity. For cosmic variance dominated surveys the signal-to-noise ratio is improved by a factor of around 20-30 on linear scales ($\ell_{\rm max}=200$), with a lower improvement of around 5-10 if one includes smaller scales ($\ell_{\rm max}=1000$). Shot noise and interferometer noise reduce the relative improvement to about 1.5-2 for the specific examples of DES and Euclid cross-correlated with HIRAX. Our estimator is additionally less susceptible to systematic effects as it only involves cross-correlations.
1907.00750
Intrinsic alignment statistics of density and velocity fields at large scales: formulation, modeling and baryon acoustic oscillation features
Okumura, Taruya, Nishimichi
1907.00978
Galactic cirri in deep optical imaging
Román, Trujillo, Montes
The ubiquitous presence of Galactic cirri in deep optical images represents a major obstacle to study the low surface brightness features of extragalactic sources. To address this issue, we have explored the optical properties of cirri using g, r, i and z bands in the Sloan Digital Sky Survey (SDSS) Stripe82 region. Using state-of-the-art $-$custom made$-$ image processing techniques, including the modeling and removal of the scattered light produced by the stars, we manage to isolate the optical diffuse emission by the cirri, allowing their photometric characterization. We find that their optical colors are driven by the dust column density: the cirri become redder as their 100 $\mu$m emission increases. This could explain the extended red emission previously found in dust clouds. In most cases, the optical colors of the Galactic cirri differ significantly from those of extragalactic sources. If future works confirm our findings, it would be possible the use of deep multi-band optical photometry (as the one produced by LSST) to identify the presence of cirri at a higher spatial resolution than those provided by far infrared observations. The combination of very deep data and multi-band photometry would make possible to build dust and extinction maps of unprecedented quality.
1907.01125
Fitting functions on the cheap: the relative nonlinear matter power spectrum
Hannestad, Wong
We propose an alternative approach to the construction of fitting functions to the nonlinear matter power spectrum extracted from $N$-body simulations based on the relative matter power spectrum $\delta(k,a)$, defined as the fractional deviation in the absolute matter power spectrum produced by a target cosmology away from a reference $\Lambda$CDM prediction. From the computational perspective, $\delta(k,a)$ is fairly insensitive to the specifics of the simulation settings, and numerical convergence at the 1%-level can be readily achieved without the need for huge computing capacity. Furthermore, $\delta(k,a)$ exhibits several interesting properties that enable a piece-wise construction of the full fitting function, whereby component fitting functions are sought for single-parameter variations and then multiplied together to form the final product. Then, to obtain 1%-accurate absolute power spectrum predictions for any target cosmology only requires that the community as a whole invests in producing one single ultra-precise reference $\Lambda$CDM absolute power spectrum, to be combined with the fitting function to produce the desired result. To illustrate the power of this approach, we have constructed the fitting function RelFit using only five relatively inexpensive $w$CDM simulations (box length $L=256 h^{-1}$Mpc, $N=1024^3$ particles, initialised at $z_i=49$). In a 6-parameter space spanning $\{\omega_m,A_s,n_s,w,\omega_b,h\}$, the output relative power spectra of RelFit are consistent with the predictions of the CosmicEmu emulator to 1% or better for a wide range of cosmologies up to $k\simeq 10$/Mpc. Thus, our approach could provide an inexpensive and democratically accessible route to fulfilling the 1%-level accuracy demands of the upcoming generation of large-scale structure probes, especially in the exploration of "non-standard" or "exotic" cosmologies on nonlinear scales.
1907.01429
The slingshot effect as a probe of transverse motions of galaxies
Hagala, et al
There are currently no reliable methods to measure transverse velocities of galaxies. This is an important piece of information that could allow us to probe the physics of structure formation as well as testing the underlying theory of gravity. The slingshot effect, a special case of the Integrated Sachs-Wolfe effect, is expected to create dipole signals in the temperature fluctuations of the Cosmic Microwave Background Radiation (CMB). This effect creates a hot spot behind and a cold spot in front of moving massive objects. The dipole signal created by the slingshot effect can be used to measure transverse velocities, but because the signal is expected to be weak, the effect has not been measured yet. The aim is to show that the slingshot effect can be measured by stacking the signals of galaxies falling into a collapsing cluster. We evaluate if the effect can probe modified gravity. We use data from a simulated galaxy catalogue (MDPL2) to mimic observations. We identify a massive galaxy cluster, and make maps of the slingshot effect around infalling galaxies. We add uncorrelated Gaussian noise to each map. The maps are rotated according to the direction to the cluster centre, such that the dipole signal will add up constructively when stacking. We compare each stack to a dipole stencil and we find the probability for a false positive in the absence of the slingshot signal. Each galaxy gives a signal of around $\Delta T/T \approx 10^{-9}$, while the precision of CMB experiments of today are $\Delta T/T \approx 4 \times 10^{-6}$. By stacking around 10 000 galaxies, the slingshot signal can be over the detectable threshold with experiments of today. However, future CMB experiments must be used to be certain of the strength of the observed signal.
1907.01542
A fast radio burst localized to a massive galaxy
Ravi, et al
Intense, millisecond-duration bursts of radio waves have been detected from beyond the Milky Way [1]. Their extragalactic origins are evidenced by their large dispersion measures, which are greater than expected for propagation through the Milky Way interstellar medium alone, and imply contributions from the intergalactic medium and potentially host galaxies [2]. Although several theories exist for the sources of these fast radio bursts, their intensities, durations and temporal structures suggest coherent emission from highly magnetised plasma [3,4]. Two sources have been observed to repeat [5,6], and one repeater (FRB 121102) has been localised to the largest star-forming region of a dwarf galaxy at a cosmological redshift of 0.19 [7, 8]. However, the host galaxies and distances of the so far non-repeating fast radio bursts are yet to be identified. Unlike repeating sources, these events must be observed with an interferometer with sufficient spatial resolution for arcsecond localisation at the time of discovery. Here we report the localisation of a fast radio burst (FRB 190523) to a few-arcsecond region containing a single massive galaxy at a redshift of 0.66. This galaxy is in stark contrast to the host of FRB 121102, being a thousand times more massive, with a greater than hundred times lower specific star-formation rate. The properties of this galaxy highlight the possibility of a channel for FRB production associated with older stellar populations.
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