Patent Number: 
Section: claims

1. A method of decontaminating areas near radioisotope-contaminated surfaces, comprising: using non-thermal laser peeling in which a substance as irradiated with pulsed laser the pulse duration of which is extremely short, ranging from several hundred femtoseconds to less than several picoseconds, is evaporated or removed from the irradiated region at a sufficiently faster speed than the energy dissipation of the laser, and the energy dissipation of laser-induced, laser-accelerated or laser-energized electrons and other particles, and the thermal effects of these energy dissipations are transmitted from the irradiated region to nearby areas, whereby the substance is peeled without suffering re-melting, re-diffusing and re-contaminating. 2. The method according to claim 1, wherein to ensure that the removed or evaporated radioisotope-containing substance will not return to the irradiated region, a fluid comprising a gas, a liquid, a spray of liquid suspension, an atomized jet gas, or a liquid-gas mixture, or fine solid particles, or a mixture of the fine solid particles and the fluid is blown simultaneously or non-simultaneously or in temporal association or in asynchronous association with the pulsed laser, whereupon the fusion between the laser and the non-laser substance causes the irradiated substance to be ground mechanically, or simply moved, or involved in a complex manner, and the irradiated substance is separately recovered through an exhaust pipe provided near the laser irradiated region, whereby the irradiated substance is removed from the irradiated region. 3. The method according to claim 1, wherein perfect decontamination is possible by combining a chemical reaction and/or a mechanical means with the non-thermal laser peeling or by applying the non-thermal laser peeling from the beginning to the end. 4. The method according to claim 1, wherein to secure a region in a water environment in a nuclear reactor pressure vessel, a container tank or the like that is gas pressurized to discharge the water so that it will not interfere with laser irradiation, the method has a semi-hermetically closed, incomplete water seal that is half-open with a siphon provided downward, has such a structure that the inner surface of each of the vessels is optionally utilized as a face to be contacted by the water seal, has a mechanical structure that withstands water pressure in a radial direction, and employs an extendable telescopic bellows-like tube or any other extendable structure that enables tilting over a wide range in an axial direction that is generally perpendicular to the surface to be irradiated with the laser. 5. The method according to claim 2, wherein perfect decontamination is possible by combining a chemical reaction and/or a mechanical means with the non-thermal laser peeling or by applying the non-thermal laser peeling from the beginning to the end. 6. The method according to claim 2, wherein to secure a region in a water environment in a nuclear reactor pressure vessel, a container tank or the like that is gas pressurized to discharge the water so that it will not interfere with laser irradiation, the method has a semi-hermetically closed, incomplete water seal that is half-open with a siphon provided downward, has such a structure that the inner surface of each of the vessels is optionally utilized as a face to be contacted by the water seal, has a mechanical structure that withstands water pressure in a radial direction, and employs an extendable telescopic bellows-like tube or any other extendable structure that enables tilting over a wide range in an axial direction that is generally perpendicular to the surface to be irradiated with the laser. 7. The method according to claim 3, wherein to secure a region in a water environment in a nuclear reactor pressure vessel, a container tank or the like that is gas pressurized to discharge the water so that it will not interfere with laser irradiation, the method has a semi-hermetically closed, incomplete water seal that is half-open with a siphon provided downward, has such a structure that the inner surface of each of the vessels is optionally utilized as a face to be contacted by the water seal, has a mechanical structure that withstands water pressure in a radial direction, and employs an extendable telescopic bellows-like tube or any other extendable structure that enables tilting over a wide range in an axial direction that is generally perpendicular to the surface to be irradiated with the laser. 8. The method according to claim 5, wherein to secure a region in a water environment in a nuclear reactor pressure vessel, a container tank or the like that is gas pressurized to discharge the water so that it will not interfere with laser irradiation, the method has a semi-hermetically closed, incomplete water seal that is half-open with a siphon provided downward, has such a structure that the inner surface of each of the vessels is optionally utilized as a face to be contacted by the water seal, has a mechanical structure that withstands water pressure in a radial direction, and employs an extendable telescopic bellows-like tube or any other extendable structure that enables tilting over a wide range in an axial direction that is generally perpendicular to the surface to be irradiated with the laser.