High precision microlensing maps of the Galactic bulge

TL;DR

This paper provides detailed, extinction-aware microlensing maps of the Galactic bulge, highlighting the importance of infrared surveys for accurate stellar and Galactic structure analysis.

Contribution

It introduces high-resolution, extinction-sensitive microlensing maps based on synthetic stellar catalogs, emphasizing the benefits of near-infrared observations.

Findings

Optical depth maps are heavily influenced by extinction effects.

Infrared surveys significantly improve sensitivity and accuracy.

Extinction effects must be carefully modeled in microlensing studies.

Abstract

We present detailed maps of the microlensing optical depth and event density over an area of 195 sq. deg towards the Galactic bulge. The maps are computed from synthetic stellar catalogues generated from the Besancon Galaxy Model, which comprises four stellar populations and a three-dimensional extinction map calibrated against the Two-Micron All-Sky Survey. The optical depth maps have a resolution of 15 arcminutes, corresponding to the angular resolution of the extinction map. We compute optical depth and event density maps for all resolved sources above I=19, for unresolved (difference image) sources magnified above this limit, and for bright standard candle sources in the bulge. We show that the resulting optical depth contours are dominated by extinction effects, exhibiting fine structure in stark contrast to previous theoretical optical depth maps. Optical depth comparisons between Galactic models and optical microlensing survey measurements cannot safely ignore extinction or assume it to be smooth. We show how the event distribution for hypothetical J and K-band microlensing surveys, using existing ground-based facilities such as VISTA, UKIRT or CFHT, would be much less affected by extinction, especially in the K band. The near infrared provides a substantial sensitivity increase over current I-band surveys and a more faithful tracer of the underlying stellar distribution, something which upcoming variability surveys such as VVV will be able to exploit. Synthetic population models offer a promising way forward to fully exploit large microlensing datasets for Galactic structure studies.