Holography devices, three-dimensional image display apparatuses including the same, and methods of processing holography images

What is claimed is: 1. A holography device, comprising: a light reaction layer configured to react with light so as to form and remove a diffraction grating; a metal thin film on the light reaction layer; a buffer layer configured to prevent deformation of the light reaction layer from affecting the metal thin film, and configured to be an exterior of the light reaction layer; and a prism or prism array on the metal thin film; wherein when first light is incident on the metal thin film while the diffraction grating is formed in the light reaction layer, surface plasmon formed on the metal thin film is diffracted so as to output a holography image, wherein a surface of the buffer layer, which contacts the light reaction layer, is deformed to have a complementary shape to a deformation of the light reaction layer, but an opposite surface of the buffer layer is not deformed, and wherein the prism or prism array is configured to adjust an inclination angle of the first light. 2. The holography device of claim 1 , wherein the light reaction layer is configured to react with second light that is not spatially uniform so as to form the diffraction grating, and wherein the light reaction layer is configured to react with third light that is spatially uniform so as to remove the diffraction grating. 3. The holography device of claim 2 , wherein the second light and the third light have a same incident direction. 4. The holography device of claim 2 , wherein the second light and the third light have an incident direction that is opposite to an incident direction of the first light. 5. The holography device of claim 2 , wherein the second light and the third light are incident through the light reaction layer. 6. The holography device of claim 2 , wherein a first uneven portion corresponding to the diffraction grating is formed in the light reaction layer by the second light, and wherein the first uneven portion is removed from the light reaction layer by the third light. 7. The holography device of claim 6 , wherein a second uneven portion is formed in the metal thin film to correspond to the first uneven portion formed in the light reaction layer. 8. The holography device of claim 2 , wherein the light reaction layer is formed of material that reacts with the light to cause piezoelectricity. 9. The holography device of claim 2 , wherein the light reaction layer comprises at least one of ZnO doped with Er, Fe:LiNbO 3 , BSO, BGO, BTO, PZT, and a light reaction polymer. 10. The holography device of claim 1 , wherein the buffer layer comprises at least one of gas, fluid, and flexible solid. 11. The holography device of claim 1 , wherein the buffer layer is between the light reaction layer and the metal thin film. 12. The holography device of claim 1 , wherein the metal thin film is between the buffer layer and the light reaction layer. 13. The holography device of claim 1 , further comprising: an electrode below the light reaction layer; wherein the electrode is configured to apply a voltage to the light reaction layer. 14. A three-dimensional (3D) image display apparatus, comprising: a light unit comprising a plurality of light source units; a holography optical unit comprising a plurality of the holography devices of claim 1 ; and a display panel configured to modulate light reproduced by the holography optical unit according to an image signal. 15. A holography device, comprising: a light reaction layer, configured to react with light so as to form and remove a diffraction grating, and comprising at least one of zinc oxide (ZnO) doped with erbium (Er), Bi 12 SiO 20 (BSO), Bi 12 GeO 20 (BGO), Bi 12 TiO 20 (BTO), and lead zirconate titanate (PZT); a metal thin film on the light reaction layer; a buffer layer configured to prevent deformation of the light reaction layer from affecting the metal thin film; and a prism or prism array on the metal thin film; wherein when first light is incident on the metal thin film while the diffraction grating is formed in the light reaction layer, surface plasmon formed on the metal thin film is diffracted so as to output a holography image, wherein a surface of the buffer layer, which contacts the light reaction layer, is deformed to have a complementary shape to a deformation of the light reaction layer, but an opposite surface of the buffer layer is not deformed, and wherein the prism or prism array is configured to adjust an inclination angle of the first light. 16. A method of processing a holography image of a holography device, the method comprising: recording the holography image on the holography device by irradiating first light to a light reaction layer of which physical properties are changed by light in order to form a diffraction grating in the light reaction layer; outputting the holography image from the holography device by irradiating second light to a metal thin film on the light reaction layer, via a prism or prism array on the metal thin film configured to adjust an inclination angle of the second light, in order to diffract surface plasmon formed on the metal thin film; and deleting the holography image from the holography device by irradiating third light to the light reaction layer in order to remove the diffraction grating; wherein a surface of a buffer layer, which contacts the light reaction layer, is deformed to have a complementary shape to a deformation of the light reaction layer, but an opposite surface of the buffer layer is not deformed. 17. The method of claim 16 , wherein the first light is not spatially uniform, and wherein the second light is spatially uniform. 18. The method of claim 16 , wherein an uneven portion corresponding to the diffraction grating is formed in the light reaction layer by the first light, and wherein the uneven portion is removed from the light reaction layer by the third light. 19. The method of claim 18 , wherein the uneven portion is also formed in the metal thin film. 20. The method of claim 16 , wherein the light reaction layer is formed of material that reacts with light in order to cause piezoelectricity. 21. The method of claim 16 , wherein the light reaction layer comprises at least one of ZnO doped with Er, Fe:LiNbO 3 , BSO, BGO, BTO, PZT, and a light reaction polymer.