Generalized Extended Uncertainty Principle Black Holes: Shadow and lensing in the macro- and microscopic realms

Abstract

Motivated by the recent work about the Extended Uncertainty Principle (EUP) black holes Mureika:2018gxl, we present in this study its extension called the Generalized Extended Uncertainty Principle (GEUP) black holes. In particular, we investigated the GEUP effects on astrophysical and micro-black holes. First, we derive the expression for the shadow radius to investigate its behavior as perceived by a static observer located near and far from the black hole. Constraints to the large fundamental length scale L* up to 2σ level were also found using the EHT data: for Sgr. A*, L* = 5.716x1010 m, while for M87*, L* = 3.264x1013 m. Under the GEUP effect, the value of the shadow radius behaves the same way as the Schwarzschild case due to a static observer, and the effect only emerges if the mass of the black hole M is around the order of magnitude of L* (or lPl). In addition, the GEUP effect increases the shadow radius for astrophysical black holes, but the reverse happens for micro-black holes. We also explored GEUP effects to the weak and strong deflection angles as an alternative analysis. For both realms, a time-like particle gives a higher value for the weak deflection angle. Similar to the shadow, the deviation is seen when the values of L* and M are close. The strong deflection angle gives more sensitivity to GEUP deviation at smaller masses in the astrophysical scenario. However, the weak deflection angle is a better probe in the micro world.