Day 1697

Thursday.


2004.13768
The rotation curve, mass distribution and dark matter content of the Mily Way fro classical Cepheids
Ablimit, et al

With the increasing numbers of large stellar survey projects, the quality and quantity of excellent tracers to study the Milky Way is rapidly growing, one of which is the classical Cepheids. Classical Cepheids are high precision standard candles with very low typical uncertainties ($<$ 3\%) available via the mid-infrared period-luminosity relation. About 3500 classical Cepheids identified from OGLE, ASAS-SN, Gaia, WISE and ZTF survey data have been analyzed in this work, and their spatial distributions show a clear signature of Galactic warp. Two kinematical methods are adopted to measure the Galactic rotation curve in the Galactocentric distance range of $4\lesssim R_{\rm GC} \lesssim 19$ kpc. Gently declining rotation curves are derived by both the proper motion (PM) method and 3-dimensional velocity vector (3DV) method. The largest sample of classical Cepheids with most accurate 6D phase-space coordinates available to date are modeled in the 3DV method, and the resulting rotation curve is found to decline at the relatively smaller gradient of ($-1.33\pm0.1$) ${\rm km\,s^{-1}\,kpc^{-1}}$. Comparing to results from the PM method, a higher rotation velocity (($232.5\pm0.9$) ${\rm km\,s^{-1}}$) is derived at the position of Sun in the 3DV method. The virial mass and local dark matter density are estimated from the 3DV method which is the more reliable method, $M_{\rm vir} = (0.822\pm0.052)\times 10^{12}\,M_\odot$ and $\rho_{\rm DM,\odot} = 0.33\pm0.03$ GeV ${\rm cm^{-3}}$, respectively.

2004.13811

Localizing merging black holes with gravitational-wave lensing

Hannuksela, et al

We report here a method that can precisely localize a merging black hole. The current gravitational-wave localization methods rely mainly on merging neutron stars or other sources with electromagnetic counterparts. However, the scientific targets of merging black holes are entirely different and they allow us to probe exciting properties such as higher-order modes, high redshifts, and the strong field of gravity. Unfortunately, the lack of an electromagnetic counterpart and the poor sky localization accuracies of the current gravitational-wave detectors make it generally difficult to localize a merging black hole precisely. However, lensed gravitational waves, whose first observation is predicted in this decade, could allow us to search for the source through locating its similarly lensed host galaxy. Specifically, a dedicated follow-up of the sky localization of the lensed gravitational wave could allow us to identify the lensed host galaxy, and to reconstruct its lens profile. Unfortunately, uniquely identifying the correct host galaxy is challenging, because there are hundreds and sometimes thousands of other lensed galaxies within the sky area spanned by the gravitational-wave observation. However, by combining the gravitational-wave information with the lens reconstructions of all the lensed galaxy candidates, we show that one can localize quadruply lensed waves to one or at most a few galaxies with the LIGO/Virgo/Kagra network. Using simulated data, we demonstrate that once the lensed host is identified, the gravitational-wave source can be localized within the host galaxy, and the system can be used to measure the Hubble constant.

2004.14192

Searching for a Black Hole n the Outer Solar System

Witten

There are hints of a novel object ("Planet 9") with a mass $5-10$ $M_\oplus$ in the outer Solar System, at a distance of order 500 AU. If it is a relatively conventional planet, it can be found in telescopic searches. Alternatively, it has been suggested that this body might be a primordial black hole (PBH). In that case, conventional searches will fail. A possible alternative is to probe the gravitational field of this object using small, laser-launched spacecraft, like the ones envisioned in the Breakthrough Starshot project. With a velocity of order $.001~c$, such spacecraft can reach Planet 9 roughly a decade after launch and can discover it if they can report timing measurements accurate to $10^{-5}$ seconds back to Earth.