The demand in Micro-Air Vehicles (MAV) is increasing as well as their potential missions. Either for discretion in military operations or noise pollution in civilian use, noise reduction of MAV is a goal to achieve. Aeroacoustic research has long been focusing on full scale rotorcrafts. At MAV scales however, the hierarchization of the numerous sources of noise is not straightforward, as a consequence of the relatively low Reynolds number that ranges typically from 5,000 to 100,000 and low Mach number of approximately 0.1. This knowledge however, is crucial for aeroacoustic optimization and blade noise reduction in drones. This contribution briefly describes a lowcost,numerical methodology to achieve noise reduction by optimization of MAV rotor blade geometry. Acoustic power measurements show a reduction of 8 dB(A). The innovative rotor blade geometry allowing this noise reduction is then analyzed in details, both experimentally and numerically with Large Eddy Simulation using Lattice Boltzmann Method (LES-LBM). Turbulence interaction noise is shown to be a major source of noise in this configuration of low Reynolds number rotor in hover, as a result of small scale turbulence and high frequency unsteady aeroadynamics impinging the blades at the leading-edge.