Abstract
We investigate the propagation of linearly polarized vortex-Gaussian beams carrying topological charge M through a rutile uniaxial crystal at arbitrary angles relative to the optical axis. Using a full vectorial numerical model, we provide a systematic mapping of how both the propagation angle θ and the topological charge jointly govern the evolution of the transverse and longitudinal electric-field components. The results reveal a pronounced and angle-dependent modulation of all field components, accompanied by a strong and predictable amplification with increasing M. In particular, the longitudinal component exhibits an M-dependent oscillatory behavior that peaks near orthogonal incidence, while the generated transverse component reaches its maximum close to parallel propagation. The phase distributions show a clear topological imprint, including a reduction of the longitudinal-field phase winding to [Formula: see text] due to anisotropy-driven coupling. These observations shed light on the coupled roles of anisotropy, propagation angle, and vortex charge in shaping the vectorial structure of light inside uniaxial crystals. The results hold relevance for applications in optical manipulation, vector-beam generation, and quantum and classical information processing.