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Heavy Water Production

     Heavy water is the key to one type of reactor in which plutonium
     can be bred from natural uranium. As such, the production of heavy
     water has always been monitored, and the material is export
     controlled. In addition, a source of deuterium is essential for
     the production of tritium and 6LiD, two ingredients of
     thermonuclear weapons. A nation seeking large quantities of heavy
     water probably wishes to use the material to moderate a reactor,
     and may be planning to produce plutonium. However, CANDU (CANadian
     Deuterium Uranium) reactors designed and built in Canada are used
     for commercial electric power production.

     Heavy water, D2O, is water in which both hydrogen atoms have been
     replaced with deuterium, the isotope of hydrogen containing one
     proton and one neutron. It is present naturally in water, but in
     only small amounts, less than 1 part in 5,000. Heavy water is one
     of the two principal moderators which allow a nuclear reactor to
     operate with natural uranium as its fuel. The other moderator is
     reactor-grade graphite (graphite containing less than 5 ppm boron
     and with a density exceeding 1.50 gm/cm 3 ). The first nuclear
     reactor built in 1942 used graphite as the moderator; German
     efforts during World War II concentrated on using heavy water to
     moderate a reactor using natural uranium.

     The importance of heavy water to a nuclear proliferator is that it
     provides one more route to produce plutonium for use in weapons,
     entirely bypassing uranium enrichment and all of the related
     technological infrastructure. In addition, heavy-water-moderated
     reactors can be used to make tritium.

     Although one speaks of “making” heavy water, deuterium is not made
     in the process; rather, molecules of heavy water are separated
     from the vast quantity of water consisting of H2O or HDO (singly
     deuterated water), and the “dross” is discarded. Alternatively,
     the water may be electrolyzed to make oxygen and hydrogen
     containing normal gas and deuterium. The hydrogen can then be
     liquefied and distilled to separate the two species. Finally, the
     resulting deuterium is reacted with oxygen to form heavy water. No
     nuclear transformations occur.

     The production of heavy water in significant amounts requires a
     technical infrastructure, but one which has similarities to
     ammonia production, alcohol distillation, and other common
     industrial processes. One may separate heavy water directly from
     natural water or first “enrich” the deuterium content in hydrogen
     gas. It is possible to take advantage of the different boiling
     points of heavy water (101.4 °C) and normal water (100 °C) or the
     difference in boiling points between deuterium (–249.7 °C) and
     hydrogen (–252.5 °C). However, because of the low abundance of
     deuterium, an enormous amount of water would have to be boiled to
     obtain useful amounts of deuterium. Because of the high heat of
     vaporization of water, this process would use enormous quantities
     of fuel or electricity. Practical facilities which exploit
     chemical differences use processes requiring much smaller amounts
     of energy. Separation methods include distillation of liquid
     hydrogen and various chemical exchange processes which exploit the
     differing affinities of deuterium and hydrogen for various
     compounds. These include the ammonia/hydrogen system, which uses
     potassium amide as the catalyst, and the hydrogen sulfide/water
     system (Girdler Sulfide process).

     Separation factors per stage are significantly larger for
     deuterium enrichment than for uranium enrichment because of the
     larger relative mass difference. However, this is compensated for
     because the total enrichment needed is much greater. While 235U is
     0.72 percent of natural uranium, and must be enriched to 90
     percent of the product, deuterium is only .015 percent of the
     hydrogen in water and must be enriched to greater than 99 percent.
     If the input stream has at least 5 percent heavy water, vacuum
     distillation is a preferred way to separate heavy from normal
     water.

     This process is virtually identical to that used to distill brandy
     from wine. The principal visible difference is the use of a
     phosphor-bronze packing that has been chemically treated to
     improve wettability for the distillation column rather than a
     copper packing. Most organic liquids are non-polar and wet
     virtually any metal, while water, being a highly polar molecule
     with a high surface tension, wets very few metals. The process
     works best at low temperatures where water flows are small, so
     wetting the packing in the column is of particular importance.
     Phosphor-bronze is an alloy of copper with .02–.05 percent lead,
     .05–.15 percent iron, .5–.11 percent tin, and .01–.35 percent
     phosphorus.

     Heavy water is produced in Argentina, Canada, India, and Norway.
     Presumably, all five declared nuclear weapons states can produce
     the material. The first commer-cial heavy water plant was the
     Norsk Hydro facility in Norway (built 1934, capacity 12 metric
     metric tons per year); this is the plant which was attacked by the
     Allies to deny heavy water to Germany. As stated above, the
     largest plant, is the Bruce Plant in Canada (1979; 700 metric
     tons/year). India’s apparent capacity is very high, but its
     program has been troubled. Accidents and shutdowns have led to
     effective limitations on production.

     The Bruce Heavy Water Plant in Ontario, Canada, is the world’s
     largest producer of D2O. It uses the Girdler Sulfide (GS) process
     which incorporates a double cascade in each step. In the upper
     (“cold,” 30–40 °C) section, deuterium from hydrogen sulfide
     preferentially migrates into water. In the lower (“hot,” 120–140
     °C) section, deuterium preferentially migrates from water into
     hydrogen sulfide. An appropriate cas-cade arrangement actually
     accomplishes enrichment. In the first stage the gas is enriched
     from 0.015% deuterium to 0.07%. The second column enriches this to
     0.35% , and the third column achieves an enrichment between 10%
     and 30% deuterium. This product is sent to a distillation unit for
     finishing to 99.75% "reactor-grade" heavy water. Only about
     one-fifth of the deuterium in the plant feed water becomes heavy
     water product. The production of a single pound of heavy water
     requires 340,000 pounds of feed water.

Sources and Methods

   * Adapted from - Nuclear Weapons Technology Militarily Critical
     Technologies List (MCTL) Part II: Weapons of Mass Destruction
     Technologies

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Updated Wednesday, October 21, 1998 4:35:26 PM