Passive chemical system for detection of gamma irradiation

What is claimed is: 1. A passive chemical system for detection of gamma irradiation made by the process of: providing silver ions in an aqueous solution encapsulated in reverse micelles comprising a block copolymer which leads to gamma-ray initiated formation of nanoparticles that have a distinctive spectra and containing a buffer with a pH of 7.0 to 10.0 and formed by co-block polymers of polystyrene block length MW 4200 to 6200 and polyacrylic acid MW 3800 to 5800 in toluene; dispersing the silver ions in transparent resins which can be painted onto surfaces; exposing the silver ions to gamma-rays; initiating reduction of the silver ions upon exposure to the gamma-rays and thereby aggregating the silver ions; and forming nanoparticles that are not visible until illuminated that indicate gamma radiation was once present. 2. A passive chemical system for detection of gamma irradiation made by the process comprising: providing a diblock copolymer capsule comprising metal ions and an aqueous mixture comprising Ag cations encapsulated in reverse micelles containing a buffer with a pH of 7.0 to 10.0 and formed by co-block polymers of polystyrene block length MW 4200 to 6200 and polyacrylic acid MW 3800 to 5800 in toluene; wherein the metal ions are silver ions; dispersing the silver ions in transparent resins which can be painted onto surfaces; providing radical scavengers; and forming silver nanoparticles after gamma radiation; wherein the silver nanoparticles are not visible until illuminated that indicate gamma radiation was once present. 3. A passive chemical system for detection of gamma irradiation comprised of Ag cations encapsulated in reverse micelles containing a buffer with a pH of 7.0 to 10.0 and formed by co-block polymers of polystyrene block length MW 4200 to 6200 and polyacrylic acid MW 3800 to 5800 in toluene that produce Ag nanoparticle upon gamma radiation and dispersed in transparent resins which can be painted onto surfaces and that are not visible until illuminated that indicate gamma radiation was once present. 4. A method of detecting gamma radiation comprising: forming a two-phase solution from an aqueous solution and an organic solvent with a block copolymer present in one of the phases; encapsulating silver ions in an aqueous solution buffer with a pH of 7.0 to 10.0 in nanocapsules formed from the block copolymer; and dispersing the nanocapsules in transparent resins which can be painted onto surfaces; wherein if gamma-radiation is present the nanocapsules are exposed to gamma-rays, which leads to initiating reduction of the silver ions and forming atoms from the silver ions, wherein the silver atoms are aggregated and produce fluorescence thus detecting gamma radiation. 5. The method of claim 4 wherein the block copolymer comprises polystyrene and polyacrylic acid.