An anomaly detector with immediate feedback to hunt for planets of Earth mass and below by microlensing

TL;DR

This paper presents an automated anomaly detection system integrated into microlensing observations, enhancing the ability to discover Earth-mass and smaller exoplanets by providing immediate feedback for targeted follow-up observations.

Contribution

It introduces an automated anomaly detector embedded in the eSTAR system, improving real-time detection and follow-up of low-mass exoplanets via microlensing.

Findings

The system operated successfully during the 2007 microlensing season.

Optimized strategies increase detection efficiency for planets below 5 M_earth.

Ground-based campaigns can potentially detect Earth-mass planets before space missions.

Abstract

(abridged) The discovery of OGLE 2005-BLG-390Lb, the first cool rocky/icy exoplanet, impressively demonstrated the sensitivity of the microlensing technique to extra-solar planets below 10 M_earth. A planet of 1 M_earth in the same spot would have provided a detectable deviation with an amplitude of ~ 3 % and a duration of ~ 12 h. An early detection of a deviation could trigger higher-cadence sampling which would have allowed the discovery of an Earth-mass planet in this case. Here, we describe the implementation of an automated anomaly detector, embedded into the eSTAR system, that profits from immediate feedback provided by the robotic telescopes that form the RoboNet-1.0 network. It went into operation for the 2007 microlensing observing season. As part of our discussion about an optimal strategy for planet detection, we shed some new light on whether concentrating on highly-magnified events is promising and planets in the 'resonant' angular separation equal to the angular Einstein radius are revealed most easily. Given that sub-Neptune mass planets can be considered being common around the host stars probed by microlensing (preferentially M- and K-dwarfs), the higher number of events that can be monitored with a network of 2m telescopes and the increased detection efficiency for planets below 5 M_earth arising from an optimized strategy gives a common effort of current microlensing campaigns a fair chance to detect an Earth-mass planet (from the ground) ahead of the COROT or Kepler missions. The detection limit of gravitational microlensing extends even below 0.1 M_earth, but such planets are not very likely to be detected from current campaigns. However, these will be within the reach of high-cadence monitoring with a network of wide-field telescopes or a space-based telescope.