MoS2　nanosheets　as　a　promising　2D　nanomaterial　have　extensive　applications　in　energy　storage　and　conversion,　but　their　electrochemical　performance　is　still　unsatisfactory　as　an　anode　for　efficient　Li+/Na+　storage.　In　this　work,　the　design　and　synthesis　of　vertically　grown　MoS2　nanosheet　arrays,　decorated　with　graphite　carbon　and　Fe2O3　nanoparticles,　on　flexible　carbon　fiber　cloth　(denoted　as　Fe2O3@C@MoS2/CFC)　is　reported.　When　evaluated　as　an　anode　for　lithium-ion　batteries,　the　Fe2O3@C@MoS2/CFC　electrode　manifests　an　outstanding　electrochemical　performance　with　a　high　discharge　capacity　of　1541.2　mAh　g(-1)　at　0.1　A　g(-1)　and　a　good　capacity　retention　of　80.1%　at　1.0　A　g(-1)　after　500　cycles.　As　for　sodium-ion　batteries,　it　retains　a　high　reversible　capacity　of　889.4　mAh　g(-1)　at　0.5　A　g(-1)　over　200　cycles.　The　superior　electrochemical　performance　mainly　results　from　the　unique　3D　ordered　Fe2O3@C@MoS2　array-type　nanostructures　and　the　synergistic　effect　between　the　C@MoS2　nanosheet　arrays　and　Fe2O3　nanoparticles.　The　Fe2O3　nanoparticles　act　as　spacers　to　steady　the　structure,　and　the　graphite　carbon　could　be　incorporated　into　MoS2　nanosheets　to　improve　the　conductivity　of　the　whole　electrode　and　strengthen　the　integration　of　MoS2　nanosheets　and　CFC　by　the　adhesive　role,　together　ensuring　high　conductivity　and　mechanical　stability.