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When heavy water is used, it is as primary coolant and a neutron moderator, not as a radiation shield...and no, heavy water is not radioactive...though it is difficult to obtain in any worthwhile quantity, and completely unnecessary for shielding. Some plants use various forms of heavy water, but not the three I know, for various reasons (one reason simply being lack of necessity).
Whether it is laced with other materials or not, or heavy water or not, water is not only one of the best radiation shields, but gives the highest linear attenuation coefficient ("squiggle") per dollar (by far!), and is readily available, harmless to us all, and presents zero problems in the way of disposal issues.
The three plants I know obviously use the Rx vessel as the primary shield. No way to avoid that in any plant design. The secondary shield is a huge tank of water in all three designs, and it is plain-ol' water, for various reasons. It has a lower squiggle than metals, so is the widest layer of shielding. This is surrounded by a tertiary shield that is lead in all three cases. This cuts radiation inside the normally serviceable area of the Rx compartment to levels that are technically survivable even at operation...although atmospheric conditions in the compartment would not permit this, nor would Rx compartment entry procedures. Even so, the inner walls of the Rx compartment are lead lined. There are also small lead glass viewing windows (thick lead-impregnated glass that has a yellow tint).
(Off topic, but FWIW, the primary source of exposure for plant operators is NOT radiation emanating directly from the Rx core. As I mentioned, this radiation is for all intents and purposes totally effectively (and fairly easily) shielded. It is radiation from beta decay of Co-60 (and subsequent gamma decay of the resultant Ni-60) carried out of the core by the primary coolant and lodged in low points of the primary system. Co-59 is found in valve seats and other wear areas of the plant, including, of course, the Nicor from which the primary plant is almost entirely constructed. As this wears, it is moved along by the primary coolant into the Rx core, where it can be blasted into Co-60. This Co-60 then finds itself settling in low areas or areas where stagnant pockets of coolant are prone to occur, and waiting to release a beta to stabilize. Unfortunately, by their nature, these areas are the areas that most often require service by humans. That is when the vast bulk of human exposure from nuclear plants actually occurs. On the plus side, if you have to get irradiated, betas aren't the worst possible thing by which to be irradiated.
Unfortunately, the Ni-60 left over after the beta decay stabilizes by emitting gammas!)
So, back to my idea...We would need to know the average types and doses of film-fogging radiation that film receives here on Earth, and I am sure that an effective shield could be designed when our beloved fast films are discontinued.
Whether it is laced with other materials or not, or heavy water or not, water is not only one of the best radiation shields, but gives the highest linear attenuation coefficient ("squiggle") per dollar (by far!), and is readily available, harmless to us all, and presents zero problems in the way of disposal issues.
The three plants I know obviously use the Rx vessel as the primary shield. No way to avoid that in any plant design. The secondary shield is a huge tank of water in all three designs, and it is plain-ol' water, for various reasons. It has a lower squiggle than metals, so is the widest layer of shielding. This is surrounded by a tertiary shield that is lead in all three cases. This cuts radiation inside the normally serviceable area of the Rx compartment to levels that are technically survivable even at operation...although atmospheric conditions in the compartment would not permit this, nor would Rx compartment entry procedures. Even so, the inner walls of the Rx compartment are lead lined. There are also small lead glass viewing windows (thick lead-impregnated glass that has a yellow tint).
(Off topic, but FWIW, the primary source of exposure for plant operators is NOT radiation emanating directly from the Rx core. As I mentioned, this radiation is for all intents and purposes totally effectively (and fairly easily) shielded. It is radiation from beta decay of Co-60 (and subsequent gamma decay of the resultant Ni-60) carried out of the core by the primary coolant and lodged in low points of the primary system. Co-59 is found in valve seats and other wear areas of the plant, including, of course, the Nicor from which the primary plant is almost entirely constructed. As this wears, it is moved along by the primary coolant into the Rx core, where it can be blasted into Co-60. This Co-60 then finds itself settling in low areas or areas where stagnant pockets of coolant are prone to occur, and waiting to release a beta to stabilize. Unfortunately, by their nature, these areas are the areas that most often require service by humans. That is when the vast bulk of human exposure from nuclear plants actually occurs. On the plus side, if you have to get irradiated, betas aren't the worst possible thing by which to be irradiated.
Unfortunately, the Ni-60 left over after the beta decay stabilizes by emitting gammas!)So, back to my idea...We would need to know the average types and doses of film-fogging radiation that film receives here on Earth, and I am sure that an effective shield could be designed when our beloved fast films are discontinued.
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) in this Underground Vaults & Storage facility? The important question is: how effective would 150 feet of limestone be at retarding cosmic ray fogging? I've asked one of my Physics PhD friends to research that, but he ran into lots of dead ends. Seems to be a really specialized field that only someone with Kodak connections has a chance of effectively probing. 
