Short-duration lensing events: I. wide-orbit planets? free-floating low-mass objects? or high-velocity stars?

TL;DR

Short-duration gravitational lensing events can reveal low-mass objects, high-velocity stars, and planetary system details, offering unique insights into nearby planets, free-floating objects, and stellar populations.

Contribution

This paper explores how short-duration lensing events can be used to detect and characterize low-mass lenses, free-floating planets, and high-velocity stars, highlighting their potential for detailed system parameter measurements.

Findings

Lensing can measure masses of nearby free-floating planets.

Short events often caused by low-mass or high-velocity lenses.

High-velocity lenses include neutron stars and hypervelocity stars.

Abstract

Short duration lensing events tend to be generated by low-mass lenses or by lenses with high transverse velocities. Furthermore, for any given lens mass and speed, events of short duration are preferentially caused by nearby lenses (mesolenses) that can be studied in detail, or else by lenses so close to the source star that finite-source-size effects may be detected, yielding information about both the Einstein ring radius and the surface of the lensed star. Planets causing short-duration events may be in orbits with any orientation, and may have semimajor axes smaller than an AU, or they may reach the outer limits of their planetary systems, in the region corresponding to the Solar System's Oort Cloud. They can have masses larger than Jupiter's or smaller than Pluto's. Lensing therefore has a unique potential to expand our understanding of planetary systems. A particular advantage of lensing is that it can provide precision measurements of system parameters, including the masses of and projected separation between star and planet. We demonstrate how the parameters can be extracted and show that a great deal can be learned. For example, it is remarkable that the gravitational mass of nearby free-floating planet-mass lenses can be measured by complementing observations of a photometric event with deep images that detect the planet itself. A fraction of short events may be caused by high-velocity stars located within a kpc. Many high-velocity lenses are likely to be neutron stars that received large natal kicks. Other high-speed stars may be members of the halo population. Still others may be hypervelocity stars that have been ejected from the Galactic Center, or runaway stars escaped from close binaries, possibly including the progenitor binaries of Type Ia supernovae.