Nanocomposites　photonic　materials　are　being　actively　studied　for　practical　applications　such　as　touch　screen,　wearable　devices,　optical　sensors,　photolithography,　and　neutron　optics.　For　many　of　these　applications,　it　is　essential　to　fabricate　embedded　phase　structures　into　media,　in　order　to　implement　various　properties　for　its　practicality.　High-contrast　refractive-index　changes　with　promising　flexibility　are　usually　desired　for　these　applications.　Photopolymers　as　an　appealing　candidate　are　attractive　because　they　hold　several　advantages,　such　as　low　cost,　ease　of　use,　shape　flexibility,　large-area　process　ability,　and　self-development　capability.　In　this　work,　we　carried　out　single-wall　nanotube　doped　polymer　composites,　which　are　based　on　acrylate-thiol-ene　photopolymer　material.　It　is　shown　that　a　substantial　increase　in　refractive　index　modulation　and　diffraction　efficiency　is　realized　by　doping　both　of　BzO(2)　and　single-wall　nanotubes.　Moreover,　the　incorporation　of　BzO(2)　lowers　the　optimum　recording　intensity　to　0.25　mW/cm(2).　These　results　indicate　that　carbon　nanotube-polymer　composite　provides　effective　method　to　fabricate　flexible　films　with　large-area　holograms　for　wearable　devices,　display,　and　optical　sensor　uses.