Mesolensing: I. High Probability Lensing Without Large Optical Depth

In a variety of astronomical situations, there is a relatively high probability that a single isolated lens will produce a detectable event. The high probability is caused by some combination of a large Einstein angle, fast angular motion, and a dense background field. We refer to high-probability lenses as mesolenses. The mesolensing regime is complementary to the regime in which the optical depth is high, in that it applies to isolated lenses instead of to dense lens fields. Mesolensing is complementary to microlensing, because it is well suited to the study of different lens populations, and also because different observing and analysis strategies are required to optimize the discovery and study of mesolenses. Planetary and stellar masses located within 1-2 kpc are examples of mesolenses. We show that their presence can be detected against a wide variety of background fields, using distinctive signatures of both time variability and spatial effects. Time signatures can be identical to those of microlensing, but can also include baseline jitter, extreme apparent chromaticity, events well fit by lens models in which several independent sources are simultaneously lensed, and sequences of events. Spatial signatures include astrometric lensing of surface brightness fluctuations, as well as patterns of time variability that sweep across the background field as the lens moves. Wide-field monitoring programs, such as Pan-STARRS and LSST, are well-suited to the study of mesolensing. In addition, high resolution observations of the region behind a known mass traveling across a background field can use lensing effects to measure the lens mass and study its multiplicity.