Method for producing deuterium-depleted water and method for producing deuterium-enriched water

The invention claimed is: 1. A method for producing deuterium-depleted water by removing heavy water and semi-heavy water from water, the method comprising: adsorbing a large amount of light water on an adsorbent including a pore body including a carbon material or an oxide while supplying water vapor to and allowing the water vapor to pass through the adsorbent for a predetermined period of time, the carbon material having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:10 or the oxide having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:5; and then desorbing the water vapor adsorbed on the adsorbent and having low concentrations of heavy water and semi-heavy water from the adsorbent to recover deuterium-depleted water. 2. A method for producing deuterium-depleted water by removing heavy water and semi-heavy water from water, the method comprising: rotating an adsorbent in a circumferential direction, the adsorbent including a pore body including a carbon material or an oxide, the carbon material having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:10 or the oxide having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:5, and disposing a supply port for water vapor and a supply port for a flow gas not containing water vapor side by side in the circumferential direction of rotation of the adsorbent; supplying water vapor to and allowing the water vapor to pass through a part of the adsorbent; and, at the same time, supplying the flow gas to and allowing the flow gas to pass through another part of the adsorbent, and desorbing the water vapor adsorbed on the adsorbent from the adsorbent to recover deuterium-depleted water. 3. A method for producing deuterium-enriched water by removing light water from water, the method comprising: adsorbing a large amount of light water on an adsorbent including a pore body including a carbon material or an oxide while supplying water vapor to and allowing the water vapor to pass through the adsorbent for a predetermined period of time, the carbon material having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:10 or the oxide having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:5, and recovering deuterium-enriched water from the water vapor not adsorbed on and passed through the adsorbent, the water vapor having high concentrations of heavy water and semi-heavy water. 4. A method for producing deuterium-enriched water by removing light water from water, the method comprising: rotating an adsorbent in a circumferential direction, the adsorbent including a pore body including a carbon material or an oxide, the carbon material having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:10 or the oxide having a pore having a length to a bottom longer than a pore diameter of an opening portion by 5 times or more and a ratio of an outer surface area of a portion that is not the pore to an inner surface area of the pore of greater than 1:5, and disposing a supply port for water vapor and a supply port for a flow gas not containing water vapor side by side in the circumferential direction of rotation of the adsorbent; supplying the water vapor to and allowing the water vapor to pass through a part of the adsorbent to adsorb a large amount of light water on the adsorbent, and recovering deuterium-enriched water from the water vapor not adsorbed on and passed through the adsorbent, the water vapor having high concentrations of heavy water and semi-heavy water; and, at the same time, supplying the flow gas to and allowing the flow gas to pass through another part of the adsorbent, and desorbing the water vapor adsorbed on the adsorbent from the adsorbent.