Measuring the gravitomagnetic distortion from rotating halos I: methods

TL;DR

This paper investigates the potential to detect gravitomagnetic effects caused by rotating galaxy clusters through lensing measurements, proposing an estimator and analyzing simulation and real data for future survey prospects.

Contribution

It introduces a new estimator for gravitomagnetic lensing effects around rotating halos and assesses its detectability using simulations and SDSS data.

Findings

Estimator accurately models gravitomagnetic lensing signals.

Simulations show the signal is consistent with zero within current noise levels.

Fast rotating clusters may be more common than previously estimated.

Abstract

Source galaxy images are distorted not only by a static gravitational potential, but also by frame-dragging induced by massive rotating objects like clusters of galaxies. Such effect is well understood theoretically, it is therefore of great interest to estimate its detectability for future surveys. In this work, we analyze the lensing convergence $\kappa$ around rotating dark matter halos. The rotation of the massive objects generates a gravitomagnetic potential giving rise to an anisotropic contribution to the lensing potential. We construct an estimator $\delta \kappa$ to describe the difference between the symmetric enhancement and reduction of $\kappa$ around the halo rotation axis, finding that it is well approximated by a function proportional to the halo velocity dispersion squared times a dimensionless angular momentum parameter. Using simulation mocks with realistic noise level for a survey like LSST, we test our estimator, and show that the signal from frame-dragging of stacked rotating lenses is consistent with zero within $1\sigma$. However, we find that the most massive cluster in SDSS DR7 spectroscopic selected group catalog has a line-of-sight rotation velocity of 195.0km/s and velocity dispersion of 667.8km/s, which is at $1.2\times 10^{-8}$ odds according to the angular momentum probability distribution inferred from N-body simulations. By studying SDSS DR7 spectroscopic selected group catalog, we show how rotating clusters can be identified, and, finding that fast rotating clusters might be more abundant than in estimates based on simulations, a detection of gravitomagnetic distortion may be at reach in future surveys