The　rapid　development　of　near-eye　display　has　put　forward　higher　requirements　for　the　resolution　and　image　quality,　while　the　performance　of　quantum　dots　(QDs)　is　virtually　unlimited　by　pixel　size,　making　them　an　ideal　material　for　the　next　generation　high-resolution　display　devices.　However,　there　are　still　significant　challenges　in　depositing　multi-color　pixels　within　the　micron　range　and　achieving　high　performance　for　the　full-color　quantum　dot　light　emitting　diodes　(QLEDs).　Herein,　a　combination　of　directional　transfer　printing　and　Langmuir-Blodgett　(LB)　technique　was　utilized　to　precisely　transfer　multi-color　QDs　arrays　in　the　predetermined　direction,　and　the　full-color　QDs　arrays　demonstrated　fantastic　morphology　and　uniform　arrangement.　As　a　result,　the　full-color　QLEDs　showed　excellent　performance　with　a　resolution　of　6350　pixels　per　inch　(PPI),　a　luminance　up　to　62,947　cd/m2　and　a　peak　external　quantum　efficiency　(EQE)　of　10.03　%.　In　addition,　pixel　spacing　layers　were　introduced　to　further　suppress　electrical　crosstalk　and　unwanted　light　emission,　and　the　redundant　part　of　emissive　layers　enabled　QDs　to　be　embedded　into　pixel　spacing　layers　readily.　The　resulting　full-color　QLEDs　with　independent　pixels　exhibited　a　same　high　resolution　of　6350　PPI,　with　a　luminance　of　35,427　cd/m2　and　a　peak　EQE　of　8.55　%.　Our　work　represents　the　best　performance　of　full-color　QLEDs　with　both　high　efficiency　and　high　resolution,　which　demonstrates　great　potential　in　the　application　of　future　near-eye　displays.　©　2025　Elsevier　Ltd