Kirigami patterned polymeric materials and tunable optic devices made therefrom

What is claimed is: 1 . A structure comprising a nanocomposite having a patterned surface defining a first row of at least two discontinuous cuts and a second row of at least two discontinuous cuts offset from the first row, wherein the first row and the second row cooperate to define a plurality of bridge structures therebetween, wherein the nanocomposite comprises a polymer and a reinforcement nanomaterial distributed therein and the nanocomposite is stretchable in at least one direction. 2 . The structure of claim 1 , wherein the respective at least two discontinuous cuts of the first row and the second row are microscale cuts. 3 . The structure of claim 1 , wherein the polymer comprises polyvinyl alcohol (PVA) and the reinforcement nanomaterial comprises a conductive nanoparticle selected from the group consisting of metals, graphene oxide, graphene, carbon nanotubes, nanowires, rods, seedling metals, and combinations thereof. 4 . The structure of claim 1 , wherein the first row and the second row define a plurality of linear structures, round structures, rectangular structures, or polygonal structures when in a stretched state. 5 . The structure of claim 1 , wherein the nanocomposite exhibits an ultimate tensile strain of greater than or equal to about 100%. 6 . The structure of claim 1 , wherein the nanocomposite exhibits an electrical conductivity of greater than or equal to about 1.5×10 3 S/cm when in a fully stretched position. 7 . A tunable optic device comprising: a tunable optic grating capable of transmitting light, wherein the tunable optic grating comprises a stretchable polymeric structure having a patterned surface defining a first row of at least two discontinuous cuts and a second row of at least two discontinuous cuts offset from the first row, wherein the first row and the second row cooperate to define a plurality of bridge structures therebetween; and a tensioning component attached to the tunable optic grating that reversibly stretches the stretchable polymeric structure in at least one direction, thereby modifying the light as it is transmitted through the stretchable polymeric structure in the tunable optic grating. 8 . The tunable optic device of claim 7 , wherein the device further comprises a source of light directed at the tunable optic grating. 9 . The tunable optic device of claim 7 , wherein the stretchable polymeric structure comprises a multilayered structure comprising at least one layer comprising a polymer. 10 . The tunable optic device of claim 9 , wherein the polymer comprises Parylene C poly(p-xylylene) polymer having a substituted chlorine group per each repeated unit. 11 . The tunable optic device of claim 9 , wherein the multilayered structure further comprises at least one metal layer. 12 . The tunable optic device of claim 11 , wherein the at least one metal layer comprises chromium (Cr). 13 . The tunable optic device of claim 7 , wherein the stretchable polymeric structure comprises at least one nanocomposite that comprises a polymer and a reinforcement nanomaterial distributed therein and the nanocomposite is stretchable in at least one direction. 14 . The tunable optic device of claim 7 , wherein the stretchable polymeric structure comprises a multilayered structure having at least one layer comprising Parylene C poly(p-xylylene) polymer having a substituted chlorine group per each repeated unit and at least one second layer comprising a nanocomposite comprising polyvinyl alcohol (PVA) and a reinforcement material comprising carbon nanotubes (CNT). 15 . A photolithographic method of making a nanocomposite having a kirigami patterned surface, the method comprising: disposing the nanocomposite on a substrate, wherein the nanocomposite comprises a polymer and a reinforcement nanomaterial distributed therein; applying a photoresist material to the nanocomposite and forming a pattern of openings in the photoresist material by exposing it to a source of light or energy; and etching the nanocomposite through the openings in the photoresist material, wherein the etching creates a pattern in the nanocomposite defining a first row comprising at least two discontinuous cuts and a second row comprising at least two discontinuous cuts offset from the first row, wherein the first row and the second row cooperate to define a plurality of bridge structures therebetween, wherein the nanocomposite is stretchable in at least one direction. 16 . The method of claim 15 , wherein the disposing of the nanocomposite comprises forming the nanocomposite on the substrate via a process selected from vacuum assisted filtration (VAF) or layer-by-layer assembly (LBL). 17 . The method of claim 15 , wherein the respective at least two discontinuous cuts of the first row and the second row are microscale cuts and the etching comprises applying oxygen plasma to the photoresist material and the nanocomposite. 18 . The method of claim 15 , wherein the polymer comprises polyvinyl alcohol (PVA) and the reinforcement nanomaterial comprises a conductive nanoparticle selected from the group consisting of: metals, graphene oxide, graphene, carbon nanotubes, nanowires, rods, seedling metals, and combinations thereof. 19 . The method of claim 15 , wherein the first row and the second row define a plurality of linear structures, round structures, rectangular structures, or polygonal structures when in a stretched state. 20 . The method of claim 15 , wherein after the etching, the nanocomposite exhibits an ultimate tensile strain of greater than or equal to about 100% and an electrical conductivity of greater than or equal to about 1.5×10 3 S/cm when in a fully stretched position.