Coupling Poynting-Robertson Effect in Mass Accretion Flow Physics

In my doctoral thesis, I have focussed my attention on radiation processes in high-energy astrophysics connected with the accretion flow physics around compact objects. Generally, a radiation field beside to exert an outward radiation pressure, there is also the presence of a radiation drag force, which both can drastically change or even halt the motion of the surrounding matter. The radiation drag force, known as Poynting-Robertson effect, acts as a dissipative force against the matter's orbital motion, removing very efficiently angular momentum and energy from it. The thesis is organised in three parts: (1) for ray-tracing purposes, I have developed a mathematical method for deriving a set of high-accurate approximate polynomial formulae to easily integrate photon geodesics in a Schwarzschild spacetime; (2) I gave two fundamental contributions in the field of the general relativistic treatment of the Poynting-Robertson effect (Lagrangian formulations and extension of the model in three dimensions); (3) I reduced the data of three accreting millisecond X-ray pulsars: IGR J00291+5934, IGR J18245-2452, and SAX J1748.9-2021. This thesis offers innovative ideas in the field of radiation processes involving the Poynting-Robertson effect in high-energy astrophysics, opening thus up future interesting perspectives both in theoretical and observational physics.