In　this　study,　we　investigated　the　effect　of　pulse　current　on　the　microstructure,　texture,　deformation　behavior,　and　mechanical　properties　of　Ti-6Al-4　V　alloys　fabricated　by　electrically　assisted　stationary　friction　stirring　welding.　With　the　increase　of　the　rotation　speed　and　peak　pulse　current,　a　lamellar　structure　precipitated　in　the　stir　zone　became　more　elongated,　resulting　in　a　higher　concentration　of　grain　orientation　distribution　and　a　larger　but　gradually　decreasing　ratio　of　high-angle　grain　boundaries.　Moreover,　the　texture　strength　increased,　but　still　remained　lower　than　that　of　the　transition　zone　on　both　sides.　The　microhardness　distribution　of　the　welded　joint　was　anisotropic　in　all　layers,　with　the　stir　zone　exhibiting　the　highest　hardness,　while　the　HAZ　was　identified　as　the　weakest　region.　The　joints　have　a　maximum　tensile　strength　of　1020.1　MPa　and　an　elongation　of　6%,　respectively.　The　tensile　strength　is　comparable　to　that　of　the　base　metal　(BM),　and　the　elongation　reaches　57.7%　of　BM.　This　improvement　is　mainly　attributed　to　grain　refinement　and　uniformly　distributed　hardness.　Furthermore,　all　tensile　fractures　were　ductile　fractures.