Abstract A topological insulator (TI) is a material that behaves as an insulator in its interior but whose surface contains conducting states. This means that electrons can only move along the surface of the material. The momentum and spin of electrons in the topological insulators are constrained to be perpendicular due to strong spin-orbit coupling. This unique coupling between current and spin-polarization may enable a host of devices impossible with other semiconductor materials. The combination of TI and ferromagnet (FM) can enable ultrahigh efficiency of the TI in converting electrical charge current into spin accumulation by transfer/orbital torque. This opens many opportunities for spintronic applications. With the TI/FM’s electrical charge/spin accumulation effect, many ground-breaking studies have demonstrated possible device operation with reduced power consumption, and the compatibility of electrically controlled devices with semiconductor integrated circuits. Despite extensive studies about this great excitement, the existence, as well as the effects, of intermediate phase in the vicinity of the TI-FM epitaxial junction is never explored. This issue is essential because the intermediate phase, if exists, would tremendously affect the TI’s electronic behavior such as the fascinating spin transfer/orbital torque and spin-momentum locking effects. These physical characteristics are at the heart for a high charge/spin current converting efficiency of the TI/FM spintronic devices. Thus a close study of interfacial configurations of TI/FM heterostructure is essential for how to improve and tailor them for charge/spin current converting. With this motivation we thoroughly investigated the intermediate phase of a Ni80Fe20/Bi2Se3 heterostructure. The results point to strong sensitivity of the intermediate phase (Fe-Se compound) to the interfacial interactions and the attendant phenomenon, such as switching of magnetic easy-axis and transport properties. The stability of the Fe-Si intermediate phase, together with those physical characteristics, was found to be variable with TI thickness. Our work suggests that the emergence of the intermediate phase plays a critical role in determining the surface state of the TI itself, as well as the functionality of the TI/FM device. Therefore, the fabrication of TI/FM devices needs to be carefully handled in order to prevent the formation of the intermediate phase. This also means that the selection of the FM is another important factor responsible for above facts.