The　kinetics　incompatibility　between　battery-type　anode　and　capacitive-type　cathode　for　sodium　ion　hybrid　capacitors　(SIHCs)　seriously　hinders　their　overall　performance　output.　Herein,　we　construct　a　SIHCs　device　by　coupling　with　quantum　grade　vanadium　nitride　(VN)　nanodots　anchored　in　one-dimensional　N/F　co-doped　carbon　nanofiber　cages　hybrids　(VNQDs@PCNFs-N/F)　as　the　freestanding　anode　and　the　corresponding　activated　N/F　co-doped　carbon　nanofiber　cages　(APCNFs-N/F)　as　cathode.　The　strong　coupling　of　VN　quantum　dots　with　N/F　co-doped　1D　conductive　carbon　cages　effectively　facilitates　the　ion/electron　transport　and　intercalation-conversion-deintercalation　reactions,　ensuring　fast　sodium　storage　to　surmount　aforesaid　kinetics　incompatibility.　Additionally,　density　functional　theory　calculations　cogently　manifest　that　the　abundant　active　sites　in　the　VNQDs@PCNFs-N/F　configuration　boost　the　Na+　adsorption/reaction　activity　well　which　will　promote　both　＂intrinsic＂　and　＂extrinsic＂　pseudocapacitance　and　further　improve　anode　kinetics.　Consequently,　the　assembled　SIHCs　device　can　achieve　high　energy　densities　of　157.1　and　95.0　Wh　kg(-1)　at　power　densities　of　198.8　and　9100.5　W　kg(-1),　respectively,　with　an　ultralong　cycling　life　over　8000　cycles.　This　work　further　verified　the　feasibility　of　kinetics-compatible　electrode　design　strategy　toward　metal　ion　hybrid　capacitors.