EP0030404A1 - Method for net decrease of hazardous radioactive nuclear waste materials - Google Patents

Method for net decrease of hazardous radioactive nuclear waste materials Download PDF

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EP0030404A1
EP0030404A1 EP80201147A EP80201147A EP0030404A1 EP 0030404 A1 EP0030404 A1 EP 0030404A1 EP 80201147 A EP80201147 A EP 80201147A EP 80201147 A EP80201147 A EP 80201147A EP 0030404 A1 EP0030404 A1 EP 0030404A1
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recited
nuclides
component comprises
neutrons
transmutation
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French (fr)
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EP0030404B1 (en
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Richard Marriott
Frank S. Henyey
Adolf R. Hochstim
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Perm Inc
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Perm Inc
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    • GPHYSICS
    • G21NUCLEAR PHYSICS; NUCLEAR ENGINEERING
    • G21FPROTECTION AGAINST X-RADIATION, GAMMA RADIATION, CORPUSCULAR RADIATION OR PARTICLE BOMBARDMENT; TREATING RADIOACTIVELY CONTAMINATED MATERIAL; DECONTAMINATION ARRANGEMENTS THEREFOR
    • G21F9/00Treating radioactively contaminated material; Decontamination arrangements therefor

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  • the invention is in the field of nuclear waste control and is particularly directed toward the elimination of long-lived radioactive nuclides of nuclear reactor waste.
  • radioactive materials are stored in the containers in the ground or under the sea. With adequate safeguards, storage for about 30 years suffices to remove the harm from relatively short-lived radioactive nuclides, but the situation is quite different for the long lived wastes. Fortunately, the majority of the fission wastes have half-lives less than one year, which means that at worst they must be.stored for 33 years to be reduced to 10 -10 of their original amount. However, eighteen fission waste products as well as all the actinide waste products have half-lives greater than one year, but less than 10 years, and it is these products that pose the long term storage problem.
  • the burial solution to the waste problem is based on the assumption that the geological formation will remain stable for the necessary containment period. While this assumption is reasonable for plutonium, for example, it is not evident for the longer lived wastes including the fission products Pd 107 , Tc 99 , I 129 CS and Zr 93 , as well as the actinides.
  • a more attractive technique involves the direct transmutation of the dangerous waste materials by neutron bombardment into innucuous materials, or at worst short lived radio- active species. Such a transmutation can be achieved, for example, by recycling waste products back into the reactor which produced them.
  • Such nuclear transformations have been discussed in the literature but have been found only applicable for effective elimination of the actinides produced by neutron capture e.g. "Advanced Waste Management Studies Progress Report", 8, BNWL-B-223(1973); H.C.Claiborne, "Neutron Induced Transmutation of High-Level Radioactive Wastes", ORNL-TM-3964,1, 24; and "High Level Radioactive Waste Management Alternatives", 4, 9, BNWL 1900 (1974).
  • the applicability of transmuting long-lived fission products as well as the actinides by neutron capture in reactors has not been regarded as practical since such a procedure reputedly produces more long term waste than it removes.
  • the invention may be characterized as a method of increasing the rate of transmutation of radioactive nuclear waste materials in excess of their natural decay rates for the more rapid conversion to stable nuclides.
  • the method comprises the steps of a) extracting the nuclear waste from the reactor fuel, either continuously or periodically, b) separating the waste into selected components of different constituents, c) storing those components composed of stable nuclides or short lived nuclides which naturally decay into stable nuclides, d) exposing those components containing long lived high risk potential nuclides to a high flux of thermal neutrons in order to induce nuclear transmutations, e) further separating of the waste after exposure to the neutrons, and repetition of steps c,d and e for transmutation of the long lived radioactive waste into stable nuclides, or to short lived nuclides which rapidly decay to stable nuclides.
  • transmutation may be defined as the change of one nuclide into another nuclide of the same or a different element by any nuclear process, natural or ariticial.
  • a beneficial transmutation can be defined as any transmutation which leads, or is part of a sequence of transmutation which leads, in a reasonably short time, from a long lived radioactive nuclide to a stable nuclide.
  • radioactive waste materials are re-cycled in a region of a high-flux of thermal neutrons to permit neutron induced transmutation.
  • Chemical and/or physical and/or isotope separation of the waste may be performed both prior to and/or after neutron irradiation.
  • FIG. 1 A block diagram of the process in accordance with the invention is shown in Figure 1.
  • U 235 or orther fissile material undergoes fission, splitting into various fission fragments and producing neutrons. Some of these neutrons are used up in maintaining the chain reaction, while others are used in transmuting the waste.
  • the waste products including the fission fragments and actinides produced by neutron irradiation of Uranium, Plutonium, and/or Thorium, are separated into various components, each component comprising one or more different elements of the waste nuclei. This separation is either chemical or physical or a combination of the two and may further include isotope separation.
  • isotope separation as for example employing a mass spectrometer, could be utilized for separation of all isotopes. Economic consideration would, however, dictate primarily a combination of chemical and physical processing. Those "good" components which include only short-lived and table elements and which do not include long-lived hazardous radioactive substances are stored to allow the decay of short-lived substances. Those "bad" components containing long-lived radioactive substances are exposed to a high flux of neutrons in order to induce transmutation. After a certain amount of exposure, these wastes are recycled through the separation/irradiation loop.
  • the high neutron flux may be produced by any of a number of methods that are often referred to as flux-trapping. These methods allow the flux in some regions of the fission reactor to be significantly higher than in other parts, making use of the strong decrease of cross sections of increasing neutron energy from thermal to MeV regime neutrons. Flux-trap reactor designs are described in, for example, U.S.patents 3,255,083; 3,341,420; 3,276,963; 3,175,955; and 2,337,475.
  • the high flux may, in the future, be produced independently of fission reactors, most notably by fusion reactors. In this case economy of reaction utilization is not critical as copious supplies of neutrons can be produced with little accompanying radioactive waste.
  • Figure 1 illustrates the inventive method generally.
  • reaction economy is an important factor i.e. fission produced sources
  • the preferred chemical/physical separation techniques is to be carried out as a two-staged process as illustrated in Figure 2.
  • stage 1 reactor products are separated into components designated, for the sake of'illustration A,B,D and D. Each component, once separated is maintained in a separate channel isolated from other components and fed to the high flux region. After transmution in the high flux region the output of any given channel will generally contain some smaller amount of the original component remaining together with additional elements. These additional elements may be "good" products designated G 1 ,G 2 ....G 6 , or other components which are long-lived and require further processing. The original domponent of each channel is thus separated in stage 2 from these additional elements as illustrated in figure 2. The recycling then occurs from the output of the stage 2 separation to the high flux region. Isotope separation may be part of stage 1 and/or stage 2 separation. Further, a specific rest stage may be provided before and/or after exposure to the neutron flux to permit decay where desired prior to further neutron exposure.
  • Figure 3 shows a general format utilized in describing the decay/transmutation sequence and figure 4 illustrates, as an example, a portion of a chart of some nuclides illustrating the transmutation possibilities.
  • Natural ⁇ decay transmutations change a nuclide into another shown directly above it, while aritificial neutron induced transmutations take a nuclide into another immediately to the right.
  • ⁇ and ⁇ + decay are not significant, and for simplicity, only one isomer of each nuclide has been considered.
  • the values shown on the vertical lines connecting nuclides are the half-life of the transmutation in hours, while the values on the horizontal line are neutron cross-sectionsiin barns.
  • Fission yields per 100 fissions are also given in the chart.
  • the direct fission yield is almost completely to neutron rich nuclides not shown, which would occur below those shown. These neutron rich -uclides rapidly undergo a series of ⁇ decays, as tabluated by Rose, P.P. and Burrows, T.W., ENDF/B Fission Product Decay Data, Aug. 1976, BNL-NCS-50545 (ENDF-243), to those nuclides which are illustrated on the chart.
  • the yield shown on the charts of Figure 3 and 4 is therefore the same yield as the direct fission products of the same atomic weight.
  • Sr 90 is a long-lived radioactive nuclide which is desired to be removed. Therefore, the transmutation from Sr 90 to Sr 91 is a beneficial transmutation. Sr 91 naturally transmutes in a short time to stable Zr 91 . On the other hand, the other neutron induced transmutations shown are not beneficial and must be minimized by choice of the separation/ irradiation loop. Y 89 ⁇ Y 90 , for example, does not involve long-lived nuclides at all and therefore the induced neutron transformation simply wastes neutrons. Sr 89 ⁇ Sr 90 not only wastes neutrons but also procudes a long-lived nuclide.
  • the Sr 89 is allowed to naturally transmute to Y 89 prior to insertion of Sr into the high neutron flux region.
  • Y is then chemically separated from the Sr to prevent its otherwise neutron usage, and the Sr is exposed to the high neutron flux to transmute to Sr 90 to Sr 91 .
  • Table 1 lists 18 long-lived radioactive fission products of concern. These "bad"nuclides are broken-up into two groups, the first group having half-lives less than 100 years, and the second group having half-lives greater than 30,000 years. In addition, there are actinide wastes not listed. In reference to figure 2, there may be up to 18 separate separation/irradiation loops for the fission products and an appropriate number of loops for the actinides, one loop for each substance.
  • The"bad" nuclides considered for elimination are listed in Table 1 and are defined primarily by the amount of radioactivity they are responsible for in the waste, after the waste has been stored for a certain length of time. Their half-life is not too long, else they provide very little radioactivity. Their half-life is not too short, else they decay during the storage period. They must be present, or at least have thepossibility of being present, in a sufficiently high concentration to contribute significant radioactivity.
  • a conservative level of activity at which a substance can be considered nearly safe is half the activity of an equal amount of U 238 .
  • This criterion is in agreement with the cutoff in half lives of 10 10 years, twice the half life of U 238 (and also twice the age of the Earth
  • the required storage time as a function of half life is shown in figure 3, with the bad nuclides indicated by dots.
  • this criterion requires a storage time of 33 years.
  • the lower group of bad nuclides requires up to 3,000 years of storage, while the upper group requires at least a million years for every nuclide in that group, and up to 1/30 the age of the earth.
  • the transmutation process must satisfy at least three criteria; (1) it must consume less energy than was produced when the waste was created, (2) it must generate of itself les hazardous waste than the destroyed and (3) must eliminate waste materials at a rate significantly greater than their natural decay rate.
  • Previous studies reported in ERDA-76-43, vol:4 indicate that only neutron absorption processed can satisfy the first criterion.
  • the major source of neutrons at present are the fission power reactors themselves. Therefore the issue of the second criterion is whether the number of neutrons produced in the power reactor is sufficient to transmute all or a substantial amount of the long-lived waste produced along with those neutrons.
  • the employment of chemical and/or physical separation of waste contained in this invention is aimed primarily toward the satisfaction of the third criterion.
  • Fission of anavrage U-235 nucleus generates ascertain amount of waste and a certain number of neutrons.
  • the question in satisfying the second criteria reduces to whether these neutrons are sufficient to transmute the waste produced.
  • the computer program further allows initial separation and periodic separation between exposures to a high thermal neutron flux.
  • a strategy for each nuclide is presented which is sufficient to meet the three criteria for successful transmutation.
  • each reactor is responsible for precessing its own waste or (2) several "power” reactors send their waste to one "transmutation” reactor.
  • the second alternative is most probably not viable since it wastes the neutrons.
  • the first possibility allows the exchange of waste between different reactors; one, for example, might handle all the cesium while another handels all the zirconium, with appropriate design differences between the reactors. The important consideration is that neutrons not be wasted.
  • any given nuclide which we label by its atomic weight A and its atomic number Z, may undergo ⁇ decay to the nuclide (Z+1,A) or it may undergo neutron absorption to the nuclide (Z,A+I).
  • the first two terms determine the loss of the nuclide due to its decay and neutron absorption while the last two terms determine its gain due to the decay or transmutation of other species.
  • nuclide which has a lower nuclide in the chain with a smaller value of ⁇ .
  • Z,A a nuclide accompanied by a lighter isotope (Z, A-1) such that ⁇ Z,A-1 ⁇ Z,A
  • the transmutations of the 18 bad isotopes have been analyzed for periods of up to about 100,000 hours (about 11 1/2 years) of irradiation in a flux of 10 16 neutrons/cm 2 sec. From Table 2, one can see that this time period ranges from orders of magnitude more than enough time to remove a nuclide to less than one half-life. The improvement of removal rate over natural decay varies from a few percent to a factor of over 10 .
  • the isotope separation provides an absolute optimum situation, and provides a measure of the inefficiency of chemical separation.
  • chemical separation two possibilities are treated for some waste components. In the first case, it is assumed that there is control over the time between fission and chemical separation. This situation is possible in liquid fission fuel reactors where the fuel and waste may, for example, be continuously cycled without shut-down of the reactor. In the second, the time between fission and separation is assumed long, as for example, in solid fuel fission reactors. The extra control allows one to separate nuclides which would otherwise decay into another element.
  • Table 3 shows the results of the computer analysis for chemical separation and for isotope separation.
  • the two cases of chemical separation are labeled a and b for separation with and without timing respectively.
  • the table is ordered by increasing half life and divided into the first and second groups previously defined in relation to Table 1.
  • a very rough measure of the hazard of nuclear waste is the total amount of each of the two groups of bad nuclide. (This measure neglects differences in biological activity, in ease of storage (i.e., geochemical effects, in half life within a group, and in the nature of the radiation emitted).
  • the waste starts with about 15 atoms per hundred fissions for the low group and 20 atoms of the high group.
  • the remaining elements most notably the large amount of CS 137 , can have the partially processed part of the element combined with the part of that element freshly separated from the recent fission waste, as indicated by the solid lines in Figure 2.
  • isotope separation would occur for zr 93 , which wastes a large number of neutrons and which has a very significant amount of Zr 93 left with the stable isotopes of Zirconium after a reasonable amount of processing has taken place. Isotope separation is significant for Cesium unless case a is utilized, because of the large number of neutrons needed. Isotope separation is also useful for Sr 90 and for the other elements on Table 4 if the amounts remaining are considered objectionable, and depending on the required neutron economy could be useful for those elements which require extra neutrons.
  • the bad nuclides are discussed in order of increasing atomic number and increasing atomic weight. It is noted that in developing a strategy for each indicidual bad nuclide, there is no interdependency between the individual bad nuclides except in the case of Pr 147 and Sm 151 .
  • the decay/transmutation chain for Se 79 is shown in Figure 7.
  • the thermal neutron absorption cross section for Se 79 is shown in Figure 7.
  • the thermal neutron absorption cross section for Se 79 is not reported (probably owing to its low abundance) and may be assumed small. Thus one may assume that no significant reduction of this isotope is possible. If however the neutron absorption cross section is found to be significant: the separation/irradiation process may be utilized with Br and Kr removed periodically to enhance neutron economy.
  • Figure 8 shows the decay/transmutation chain for Kr 85 .
  • Only about 20% of the A 85 waste ends up as radio- active K r 85 .
  • Kr 83 has by far the largest neutron absorption cross section.
  • K r 84 and Kr 86 each have a cross section about 1/20 of Kr 85 .
  • Kr 83 When the Kr is subject to the neutron flux K r 83 is converted into Kr 84 . At this point the ratio of Kr 84 to Kr 85 is about 5. This ratio cannot exceed 20 (the ratio of the cross sections of Kr 85 and Kr 84 ). Therefore, after about 75% of the Kr 85 has been transmuted, it becomes difficult to convert any more Kr . For every 20 atoms of Kr converted to Kr , only 21 are converted to Kr 86 . Meanwhile about 30 Kr 86 ,s are transmuted. Thus it takes about 70 neutrons to gain 1 K r 85 .
  • Sr 90 is transmuted according to the exponential law, since the only other isotope of Strontium in the waste is stable Sr 88 which transmutes to Sr 89 with a very small cross section. Sr 89 is initially present in the waste (as well as being produced from Sr 88 ), but it decays with a half life of 1250 hours, short compared to the relevant time scale for the transmutation of Sr 90 .
  • the program WASTE was utilized with chemical processing every 3000 hours. No indication of undesirable effects of the build-up of Yttrium and Zirconium were noted. Clearly a much less frequent chemical processing for separation of Y and Zr from Sr would suffice. Only 1.06 neutrons are required for each transmutation of the first 96% of the Sr 90 . The effective half life of Sr 90 in a flux of 10 16 neutrons per square cm per second is 2-1/4 years.
  • More of the nuclear waste is Zirconium (15%) than any other single element.
  • the stable isotopes in the waste are Zr 91 , Zr 92 , Zr 94 , and 96 93 Zr .
  • Zr has a larger neutron absorption cross section than any of the stable isotopes, it is not larger enough to make transmutation easy.
  • Figure 10 shows a portion of the decay/transmutation chain including Zr 93 .
  • the initial chemical separation is carried out in a time short compared to two months after the fission process.
  • the Yttrium is separated from the Zirconium.
  • the Y 91 with a half life of about two months, decays into stable Zr 91 , which therefore is isolated from the 93 92 93 94 95 96 Zr 93 .
  • the Zr 92 , Zr 93 , Zr 94 , Zr 95 and Zr 96 are then allowed to stand, allowing the Zr 95 to decay (with a half life also of about two months).
  • the Zr 91 is included. After 50,000 hours (about 6 years) the Zr 91 has addes an extra 6% of the original Zr 93 by the sequential transmutation chain, Zr 91 ⁇ Zr 92 ⁇ Zr 93 atom removed. In both cases, neutron economy is enhanced by periodically separating Zr from Nb and Mo.
  • Tc 99 whose decay/transmutation chain is shown in Figure 12, provides one of the most favorable cases for transmutation. It has a reasonably large cross section for neutron absorption and there is only the single isotope, T c 99 , in the waste. Therefore the removal follows an exponential curve (with an effective half life of 42 days). After chemical processing, all the Tc can be combined, since it is all T c 99 . With chemical processing ecery 300 hours, the neutron usage is 1.03 neutrons per transmutation. The extra 3% comes from absorption in Ru 100 which builds up for the 300 hours.
  • Ru 106 whose decay/transmutation chain is shown in Figure 13, has a half life of 1.01 years, just above the cutoff of 1 year. It requires 33.4 years to decay to half the activity of U 238 . It has a very small neutron absorption cross section, 146 barns, requiring an exposure to neutrons for 31.4 years to reduce the activity to the same level. The saving of 2 years is not deemed worth the trouble and expense of cycling and processing. Therefore Ru 106 may be treated as a short-lived isotope, storing it for at least 33-1/2 years before allowing it to enter the environment.
  • the decay/transmutation chain for Pd 107 is shown in Figure 13. There is not much Pd 107 in the waste since it is on the high side of the lighter bump in the fission yield curve.
  • Pd105 with an atomic weight smaller by only 2, has 6 times the fission yield.
  • Ru 106 has an intermediate yield, and decays to Pd 106 (in two stept) with a half life of 1 year. Ruthenium is assumed to be separated from the Palladium before a significant amount of it has been allowed to decay (if processing occurs within half a year after fission, the results are not substantially modified).
  • the Pd 105 has a cross section 40% larger than Pd 107 , which when multiplied by the factor of 6 in yield gives a conversion rate 8.4 times that of Pd 107 .
  • Pd 107 transmuted to Pd 108 , which, with a roughly comparable cross section, converts to Pd 109 which rapidly decays.
  • Pd 107 in the early stages of transmutation it takes over 10 neutrons for each transmutation of a Pd 107 atom.
  • Sn 126 and Sb 125 are shown in Figure 14. These isotopes occur at the minimum of the yield curve, and are present in very small amounts. As a result, neutron economy is not of paramount importance and the products I and Te need not generally be separated. They are treated together because exposure of tin to neutrons produces S b 125 .
  • the cross section for Sn 126 is very small, so transmutation is very slow. After about 12 years in a flux of 10 16 neutrons/cm 2 sec., one third of the original Sn 126 still remains. However, this corresponds to .3% of any one of the five most common bad isotopes. Sb 125 is easily removed. 129
  • I 129 ( Figure 15) is removed following an exponential curve, since I 128 is highly unstable.
  • the neutron use does not exceed 1.2 neutrons per I 129 atom transmuted, as the I 129 is accompanied by 1/5 as much I 127 .
  • the situation is even more favorable since the cross section for I 127 is smaller.
  • the average use was 1.1 neutrons per transmutation, as only about half of the I 127 was removed.
  • Iodine may readily be separated from the fission waste and is thus a very favorable element for waste transmutation.
  • Cs 135 and Cs 137 are somewhat separate problems, and are discussed separately.
  • Cs 134 is not a direct fission product and therefore occurs in small amounts in the waste. It has a large cross section and is easily removed in the treatment of Cs 135 and Cs 137 .
  • Figure 16 shows a portion of the decay/transmutation chain including Cesium.
  • Cs 135 The major problem with the treatment of C s 135 is the large amount (6.75 atoms/100 fissions) of stable Cs 133 in the waste.
  • Cs 133 has a considerably higher neutron absorption cross section than Cs135, and must absorp 3 neutrons before again becoming a stable nuclide.
  • the chain is Cs 133 ⁇ Cs 135 ⁇ Cs 136 ⁇ Ba 136 .
  • Xe 133 has a half life of over 5 days, and Xe 135 has a half life of over 9 hours.
  • Xe 135 has an extremely high neutron absorption cross section (3x106 barns) and stable Xe 136 has a very small cross section (. 16 barns).
  • Stable X e 134 also has a rather small cross section (1.73 barns).
  • Cesium may be efficiently treated.
  • a liquid fuel reactor would clearly be desirable in achieving these short processing times, since the processing may be continuous.
  • Xenon As soon as Xenon is separated out, it is exposed to a high neutron flux for a short time. At 10 16 neutrons/cm 2 sec., the optimum time is 11 minutes. In the example of Tabel 3, 20 minutes was used. After this irradiation the Xenon is removed from the flux and stored for, say,two months for the Xe 133 to decay (this is about 30 half lives of Xe133). After this, the Xenon left is not radioactive. There may be a further separation of the Cesium produced in the first two hours after fission. Thus there are three, possibly four, places in which Cesium is produced.
  • the Cesium produced before separation consists of some or most of the Cs 137 and a small amount of CS 135 and C s 133 .
  • the amounts depend on the time before separation.
  • the Cesium produced during the irradiation is some or most of the Cs 137 , and a small amount of Cs 135 and Cs 133 .
  • Cs 137 is produced, and it might be desirable to keep it with the Cesium produced in the first two steps. After 2 hours, most of the Cs 133 is produced.
  • This Cs 133 would not be subject to further irradiation
  • the amount of Cs 135 that is contained in with this Cs 133 is 4.4 x 10 -6 atoms per 100 fissions (22 parts per billion of the waste), coming from the equilibrium between Xe 134 and Xe135.
  • Figure 17 shows the amount of Cs 133 and Cs 135 produced up to end of the time of irradiation as a function of the time of separation. If, for example, separation is accomplished in 6 minutes, there will be 0.055 atoms of C s 135 per 100 fissions. In the first two hours after irradiation 0.08 atoms of Cs 133 per 100 fissions out of a total of 6.75 are produced.
  • Cs 137 has the smallest neutron absorption cross section of any of the bad nuclides (with the possible exception of Se 79 ). Irradiation in a flux fo 1 0 16 neutrons/ cm 2 sec. only brings the effective half life to 12 years, compared to 30 years for natural decay. Aside from a small amount of Cs 137 generated from Cs 135 ⁇ Cs 136 ⁇ Cs 157 , Cs 137 removal follows an exponential n curve (most Cs 136 decays to Ba 136 ).
  • Pm 147 (figure 19) is the lightest isotope of Promethium in the waste, and the only one with a large half life. It is transmuted following an exponential curve with an effective half life of 4-1/3 days in a flux of 10 16 neutrons/cm sec.
  • Sm151(figure 19) is accompanied by a larger amount of S m 149
  • Sm 151 has a large neutron absorption cross section (1.4 x 10 4 barns) but Sm 149 has an even larger cross section by nearly a factor of five.
  • Europium (figure 19 & 21) is one of the heaviest elements in the waste, and occurs in small amounts. Eu 152 and Eu 154 do not occur directly as fission products. What little Eu 152 does occur will be rapidly transmuted while the Eu 155 is being removed, as wil the Eu 151 coming from the Sm 151 that decayed before it was transmuted.
  • Transmutation of Eu 155 per se is very simple, as indicated by the "isotope separation" columns of table 3.
  • the waste contains some Eu 153 , which is converted to radioactive Eu 154 . Therefore, in order to remove the Eu 155 it is necessary to convert the Eu 153 by the chain
  • the Eu 156 would have time to decay, terminating the chain at Gd, saving up to 40% of the neutrons.
  • Fig.22 shows the time development of the amounts of Eu 154 and Eu 155 .
  • the initial Eu 155 is rapidly transmuted away, while the Eu 154 builds up almost as fast as the Eu 155 is removed.
  • the Eu 154 continues to build up while it, in turn, transmutes to Eu 155 .
  • the Eu 154 and Eu155 are in equilibrium with the remaining Eu 153 and then are removed at a rate determined by the Eu 153 cross section.
  • the amounts and composition of the actinides depends on the parameters of the reactor system such as the enrichment of the Uranium and the integrated flux to which it has beenexposed.
  • this Np237 If this Np237 is exposed to as high a flux as possible , it-first transmutes to Np 238 which then fissions if it absorbs a neutron or decays to Pu 238 . The fissioning is preferable on the grounds of neutron economy.
  • U2308 if it absorbs a neutron, becomes Pu 239
  • This plutonium (as well as the Pu 238 discussed above) is, on separation, used as a fissionable substance. In thermal fission, 3/4 is fissioned and 1/4 becomes Pu 240 .
  • the Pu 240 absorbs a neutron becoming Pu 241 , Three-fourths of Pu 241 fissions and 1/ 4 becomes Pu 242 .
  • Pu 242 and heavier isotopes are not fissionable with high probability and form part of the heavy actinide waste. By sequential neutron absorption, these eventually lead to fission.
  • Fissionable isotopes include Cm 245 , Cm 247 , Bk 250 , Cf 249 . Vg 251 , and Es 254 .
  • the number of neutrons required per atom of p u 242 is large, the very small quantities involved makes the neutron usage not have a serious effect on the total neutron economy. This is consistent with the conclusion of earlier studies that actinides can be reduced by transmutation.
  • the neutron economy is approximately a net loss of one neutron for each atom of Np237 (including the absorption on U 236 ) and approximately a balance (a small net loss) for each atom of U 238 transmuted.
  • the fission wastes from Plutonium and other actinides increase the amount of fission wastes that must be processed by the excess neutrons from the fission of U 235 .

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Abstract

A method for decreasing the amount of hazardous radioactive reactor waste materials by separating from the waste of materials having long-term risk potential and exposing these materials to a thermal neutron flux. The utilization of thermal neutrons enhances the natural decay rates of the hazardous materials while the separation for recycling of the hazardous materials prevents further transmutation of stable and short-lived nuclides.

Description

  • The invention is in the field of nuclear waste control and is particularly directed toward the elimination of long-lived radioactive nuclides of nuclear reactor waste.
  • The difficulties encountered in attempting to safely dispose of radio-active wastes generated by the fission process in nuclear reactors is probably the largest single cause of public resistance to the construction of nuclear power stations. A decade ago it was liberally estimated that 200,000 megawatts of nuclear generated electricity would be available by 1980. Today this expectation is down by one half. A major argument against permitting the further spread of nuclear power involves concern over methods proposed for disposal of the nuclear waste products. Present methods of disposal of nuclear waste, which may be in the gaseous, liquid or solid state consist either of dilution and dispersion or storage..In the first approach radioactive gases or liquids are diluted with large volumes of air or water to reduce the activity per unit volume to an allegedly safe level and released into the environment. In the second use, radioactive materials are stored in the containers in the ground or under the sea. With adequate safeguards, storage for about 30 years suffices to remove the harm from relatively short-lived radioactive nuclides, but the situation is quite different for the long lived wastes. Fortunately, the majority of the fission wastes have half-lives less than one year, which means that at worst they must be.stored for 33 years to be reduced to 10-10 of their original amount. However, eighteen fission waste products as well as all the actinide waste products have half-lives greater than one year, but less than 10 years, and it is these products that pose the long term storage problem. To ensure that long lived waste products are kept out of the biosphere until they become harmless- involving periods of hundreds of thousands or millions of years - present proposals involve burial in geological salt formations or other formations such as granite, quartzite, tuff (welded volcanic ash) and shale.
  • The burial solution to the waste problem is based on the assumption that the geological formation will remain stable for the necessary containment period. While this assumption is reasonable for plutonium, for example, it is not evident for the longer lived wastes including the fission products Pd107, Tc99, I 129 CS and Zr 93, as well as the actinides.
  • In view of the extreme hazard that would be created if these materials were not be released into the biosphere, there is a strong and growing resistance to the "bury it and forget it" philosophy, and this opposition has now developed to the point of significantly slowing the growth of nuclear power. It is therefore most desirable if a method could be found to completely eliminate the noxious radioactive wastes from the environment.
  • Two methods have been suggested for such a final solution to the waste problem. Extraterrestrial disposal would permanently remove the wastes by transportation by rocket into the sun. Two major problems face this technique. First the cost, and second, but more significant, there is the possibility of vehicle failure with the atmosphere leading to a highly dangerous level of radioactive contimination.
  • A more attractive technique involves the direct transmutation of the dangerous waste materials by neutron bombardment into innucuous materials, or at worst short lived radio- active species. Such a transmutation can be achieved, for example, by recycling waste products back into the reactor which produced them. Such nuclear transformations have been discussed in the literature but have been found only applicable for effective elimination of the actinides produced by neutron capture e.g. "Advanced Waste Management Studies Progress Report", 8, BNWL-B-223(1973); H.C.Claiborne, "Neutron Induced Transmutation of High-Level Radioactive Wastes", ORNL-TM-3964,1, 24; and "High Level Radioactive Waste Management Alternatives", 4, 9, BNWL 1900 (1974). The applicability of transmuting long-lived fission products as well as the actinides by neutron capture in reactors has not been regarded as practical since such a procedure reputedly produces more long term waste than it removes.
  • It is therefore a general object of the invention to reduce the amount of-'radioactive waste and in particular fission products in nuclear reactors so that time storage requirements may be reduced from those required for natural radioactive decay.
  • The invention may be characterized as a method of increasing the rate of transmutation of radioactive nuclear waste materials in excess of their natural decay rates for the more rapid conversion to stable nuclides.
  • The method comprises the steps of a) extracting the nuclear waste from the reactor fuel, either continuously or periodically, b) separating the waste into selected components of different constituents, c) storing those components composed of stable nuclides or short lived nuclides which naturally decay into stable nuclides, d) exposing those components containing long lived high risk potential nuclides to a high flux of thermal neutrons in order to induce nuclear transmutations, e) further separating of the waste after exposure to the neutrons, and repetition of steps c,d and e for transmutation of the long lived radioactive waste into stable nuclides, or to short lived nuclides which rapidly decay to stable nuclides.
  • These and other objects of the invention will become clear in relation to the following specification taken in conjunction with the drawings wherein:
    • Figure 1 is a block diagram of the overall waste transmutation method and system in accordance with the invention;
    • Figure 2 is a block diagram of a preferred embodiment of the separation/irradiation treatment cycle;
    • Figure 3 is an illustration of the format utilized to deposit the decay/transmutation chain in general;
    • Figure 4 illustrates a protion of the decay/ transmutation chain for a specific nuclide;
    • Figure 5 is a chart of the fission fragment decay times as compared to one-half the decay activity of U238;
    • Figure 6 is a block diagram illustrating neutron economy in the fission reactor process;
    • Figure 7 represents the decay/transmutation chain for Se 79;
    • Figure 8 represents the decay/transmutation chain for Kr 85 and Sr 90
    • Figure 9 is a chart showing the removal of Kr85 as compared to its natural decay;
    • Figure 10 represents the decay/transmutation chain for Zr 93;
    • Figure 11 is a chart showing the removal of Zr 93 for both chemical and isotope separation;
    • Figure 12 represents the decay/transmutation chain for Tc 99;
    • Figure 13 represents the decay/transmutation chain for Ru106 and pd107 ;
    • Figure 14 represents the decay/transmutation chain for Sn 126 and Sb 125
    • Figure 15 represents the decay/transmutation chain for Sn126 and I129;
    • Figure 16 represents the decay/transmutation chain for the Cesium isotopes;
    • Figure 17 is a graph slowing the amount of Cs135 and Cs133 as a function of Xenon removal time after fission;
    • Figure 18 is a graph showing the amount of Cs133. Cs134 and Cs135 as a function of time;
    • Figure 19 represents the decay/transmutation chain for Pm 147 and Sm 151
    • Figure 20 is a graph showing the removal of Sm151 as a function of time;
    • Figure 21 represents the decay/transmutation chain for Eu154 and Eu155; and
    • Figure 22 is a graph showing the time development of Eu154 and Eu155.
  • As used herein, the term transmutation may be defined as the change of one nuclide into another nuclide of the same or a different element by any nuclear process, natural or ariticial. A beneficial transmutation can be defined as any transmutation which leads, or is part of a sequence of transmutation which leads, in a reasonably short time, from a long lived radioactive nuclide to a stable nuclide.
  • In accordance with the principle of the invention, radioactive waste materials are re-cycled in a region of a high-flux of thermal neutrons to permit neutron induced transmutation. Chemical and/or physical and/or isotope separation of the waste may be performed both prior to and/or after neutron irradiation.
  • This separation has several benefits:
    • 1. It minimizes the waste of neutrons which would occur in thenon-beneficial transmutation of a stable nuclide into another nuclide.
    • 2. It minimizes the production of long-lived radio- active nuclides from transmutation of stable nuclides.
    • 3. It minimizes the amount of material that has to be handles in the exposure to the high flux.
    • 4. It maximizes the beneficial use of the available neutrons in reducing the radioactive waste hazard.
  • A block diagram of the process in accordance with the invention is shown in Figure 1. U235 or orther fissile material undergoes fission, splitting into various fission fragments and producing neutrons. Some of these neutrons are used up in maintaining the chain reaction, while others are used in transmuting the waste. The waste products, including the fission fragments and actinides produced by neutron irradiation of Uranium, Plutonium, and/or Thorium, are separated into various components, each component comprising one or more different elements of the waste nuclei. This separation is either chemical or physical or a combination of the two and may further include isotope separation. In principle, isotope separation, as for example employing a mass spectrometer, could be utilized for separation of all isotopes. Economic consideration would, however, dictate primarily a combination of chemical and physical processing. Those "good " components which include only short-lived and table elements and which do not include long-lived hazardous radioactive substances are stored to allow the decay of short-lived substances. Those "bad" components containing long-lived radioactive substances are exposed to a high flux of neutrons in order to induce transmutation. After a certain amount of exposure, these wastes are recycled through the separation/irradiation loop.
  • The high neutron flux may be produced by any of a number of methods that are often referred to as flux-trapping. These methods allow the flux in some regions of the fission reactor to be significantly higher than in other parts, making use of the strong decrease of cross sections of increasing neutron energy from thermal to MeV regime neutrons. Flux-trap reactor designs are described in, for example, U.S.patents 3,255,083; 3,341,420; 3,276,963; 3,175,955; and 2,337,475.
  • Alternatively, the high flux may, in the future, be produced independently of fission reactors, most notably by fusion reactors. In this case economy of reaction utilization is not critical as copious supplies of neutrons can be produced with little accompanying radioactive waste. Figure 1 illustrates the inventive method generally.
  • Where reaction economy is an important factor i.e. fission produced sources, the preferred chemical/physical separation techniques is to be carried out as a two-staged process as illustrated in Figure 2.
  • In stage 1, reactor products are separated into components designated, for the sake of'illustration A,B,D and D. Each component, once separated is maintained in a separate channel isolated from other components and fed to the high flux region. After transmution in the high flux region the output of any given channel will generally contain some smaller amount of the original component remaining together with additional elements. These additional elements may be "good" products designated G1,G2....G6 , or other components which are long-lived and require further processing. The original domponent of each channel is thus separated in stage 2 from these additional elements as illustrated in figure 2. The recycling then occurs from the output of the stage 2 separation to the high flux region. Isotope separation may be part of stage 1 and/or stage 2 separation. Further, a specific rest stage may be provided before and/or after exposure to the neutron flux to permit decay where desired prior to further neutron exposure.
  • The choice of separation/irradiation strategies depends, in addition to economic and chemical considerations, on the transmutations possible. Figure 3 shows a general format utilized in describing the decay/transmutation sequence and figure 4 illustrates, as an example, a portion of a chart of some nuclides illustrating the transmutation possibilities. Natural β decay transmutations change a nuclide into another shown directly above it, while aritificial neutron induced transmutations take a nuclide into another immediately to the right. α and β + decay are not significant, and for simplicity, only one isomer of each nuclide has been considered. The values shown on the vertical lines connecting nuclides are the half-life of the transmutation in hours, while the values on the horizontal line are neutron cross-sectionsiin barns.
  • Fission yields per 100 fissions are also given in the chart. The direct fission yield is almost completely to neutron rich nuclides not shown, which would occur below those shown. These neutron rich -uclides rapidly undergo a series of β decays, as tabluated by Rose, P.P. and Burrows, T.W., ENDF/B Fission Product Decay Data, Aug. 1976, BNL-NCS-50545 (ENDF-243), to those nuclides which are illustrated on the chart. The yield shown on the charts of Figure 3 and 4 is therefore the same yield as the direct fission products of the same atomic weight. The document Permanent Elimination of Radioactive Hastes by Nuclear Transmutation, Physical Dynamics, Inc. PD-LJ-79-204, August, 1979 by Frank S.Henyey, the whole of which is incorporated hereinby reference, gives further details of the assumptions and computer analysis given herein.
  • Sr90 is a long-lived radioactive nuclide which is desired to be removed. Therefore, the transmutation from Sr 90 to Sr91 is a beneficial transmutation. Sr91 naturally transmutes in a short time to stable Zr91. On the other hand, the other neutron induced transmutations shown are not beneficial and must be minimized by choice of the separation/ irradiation loop. Y89 → Y90, for example, does not involve long-lived nuclides at all and therefore the induced neutron transformation simply wastes neutrons. Sr89Sr 90 not only wastes neutrons but also procudes a long-lived nuclide. As described more fully hereinafter, the Sr89 is allowed to naturally transmute to Y89 prior to insertion of Sr into the high neutron flux region. Y is then chemically separated from the Sr to prevent its otherwise neutron usage, and the Sr is exposed to the high neutron flux to transmute to Sr90 to Sr91.
  • Table 1 lists 18 long-lived radioactive fission products of concern. These "bad"nuclides are broken-up into two groups, the first group having half-lives less than 100 years, and the second group having half-lives greater than 30,000 years. In addition, there are actinide wastes not listed. In reference to figure 2, there may be up to 18 separate separation/irradiation loops for the fission products and an appropriate number of loops for the actinides, one loop for each substance.
  • The"bad" nuclides considered for elimination are listed in Table 1 and are defined primarily by the amount of radioactivity they are responsible for in the waste, after the waste has been stored for a certain length of time. Their half-life is not too long, else they provide very little radioactivity. Their half-life is not too short, else they decay during the storage period. They must be present, or at least have thepossibility of being present, in a sufficiently high concentration to contribute significant radioactivity.
  • With these qualitative criteria in mind, the following somewhat arbitrary quantitative definition of a bad fission product nuclide is utilized:
    • 1. Its half life is greater than 1 year;
    • 2. Its half life is less than 10 10 years;
    • 3. Its atomic weight is between A=72 and A=167, since these are the limits of fission product compilations, and the yields outside this range are below the part per billion level.
    • 4. It is descended from neutron-rich nuclear species by either (a) β decays or (b) a combination of decays and neutron absorptions. However, β decay chains through nuclides of half life greater than 104 years are not considered. Exceptions to this rule are present at the 10 parts per billion level in the waste.
    • 5. The excited states Sn121m, Ho166m and Cd113m are excluded.
  • A conservative level of activity at which a substance can be considered nearly safe is half the activity of an equal amount of U238. This criterion is in agreement with the cutoff in half lives of 1010 years, twice the half life of U238 (and also twice the age of the Earth The required storage time as a function of half life is shown in figure 3, with the bad nuclides indicated by dots. For our one-year cutoff in half life, this criterion requires a storage time of 33 years. The lower group of bad nuclides requires up to 3,000 years of storage, while the upper group requires at least a million years for every nuclide in that group, and up to 1/30 the age of the earth.
  • The transmutation process must satisfy at least three criteria; (1) it must consume less energy than was produced when the waste was created, (2) it must generate of itself les hazardous waste than the destroyed and (3) must eliminate waste materials at a rate significantly greater than their natural decay rate. Previous studies reported in ERDA-76-43, vol:4 indicate that only neutron absorption processed can satisfy the first criterion. The major source of neutrons at present are the fission power reactors themselves. Therefore the issue of the second criterion is whether the number of neutrons produced in the power reactor is sufficient to transmute all or a substantial amount of the long-lived waste produced along with those neutrons. The employment of chemical and/or physical separation of waste contained in this invention is aimed primarily toward the satisfaction of the third criterion. In the case of the actinides, both as a consequence of their large neutron capture probabilities and because their final removal by fission is accompanied by regeneration of some of the neutrons absorbed, all three criteria can be met. However, when the fission wastes are included, earlier studies cited above, not incorporating the principles of the invention, concluded that the second and third criteria could not be met. The invention is directed toward meeting all three criteria.
  • With regard to the second criterion, it is convenient to perform the transmutation in the power reactors themselves. Fission of anavrage U-235 nucleus generates ascertain amount of waste and a certain number of neutrons. The question in satisfying the second criteria reduces to whether these neutrons are sufficient to transmute the waste produced.
  • More specifically, one may consider the fate of the neutrons produced from 100 fissions of U 235 as illustrated in figure 6. All neutrons are considered to be thermalized. Of the 244 neutrons produced, 117 are required to maintain the chain reaction, causing 100 additional fissions and 17 absorptions without fission. The remaining 127 neutrons are absorbed in various ways including being absorbed in U 238, procuding actinide waste and ultimately more fission waste, and being absorbed in the moderator and structure of the reactor. Those remaining are available for waste transmutation. Of the 200 fission products there are 35 long-lived radio- active nuclei (plus those from fission of Plutonium and actinide wastes). This waste requires at least 35 of the, at most, 127 neutrons in order to accomplish the transmutation. Without the principles of the invention, many more than 35, and even more than 127, neutrons will be required.
  • To establish whether there are sufficient neutrons to eliminate the associated waste products, it is necessary to study the transmutation-decay chain information on all nuclides which are placed in the high flux region. The most important such nuclides are the isotopes of those elements including the long-lived radioactive fission products of which the eighteen most important radioactive nuclides are listed in Table 1. The nuclide symbol and half-life are listed in the first two columns. The cross sections which determine the neutron-induced transmutation rates are listed in the third column. The approximate amounts (per 100 fissions) in the nuclear waste is given in column 4. Column 5 gives the name of the element.
  • A computer program, WASTE, listed in appendix A was utilized to study the chains for all eighteen fission waste products. This program constructs a solution of a large set of coupled differential equations describing the transmutations. The form of these equations is that the time rate of change of any nuclide is equated to a sum of up to four terms as follows:
    • 1. The decrease of the nuclide by natural decay.
    • 2. The decrease of the nuclide by neutron-induced transmutation into another nuclide.
    • 3. The increase of the nuclide from neutron-induced transmutation of another nuclide.
  • The computer program further allows initial separation and periodic separation between exposures to a high thermal neutron flux. A strategy for each nuclide is presented which is sufficient to meet the three criteria for successful transmutation.
  • In utilizing fission reactors, it is possible that (1) each reactor is responsible for precessing its own waste or (2) several "power" reactors send their waste to one "transmutation" reactor. In as much as neutrons are in short supply, and the second alternative is most probably not viable since it wastes the neutrons. The first possibility, of course, allows the exchange of waste between different reactors; one, for example, might handle all the cesium while another handels all the zirconium, with appropriate design differences between the reactors. The important consideration is that neutrons not be wasted.
  • Any given nuclide, which we label by its atomic weight A and its atomic number Z, may undergo β decay to the nuclide (Z+1,A) or it may undergo neutron absorption to the nuclide (Z,A+I). The rate constants for these processes are αZ,A =ℓn 2/
    Figure imgb0001
    and σZAφ respectively,
    where
    Figure imgb0002
    is the nuclides half life and σZA is its neutron absorption cross section, while φ is the effective flux. Thus the amounts NZ,A of the nuclides obey the set of differential equations
    Figure imgb0003
  • The first two terms determine the loss of the nuclide due to its decay and neutron absorption while the last two terms determine its gain due to the decay or transmutation of other species.
  • The solution of this equation has the form
    Figure imgb0004
    where λZ',A' - αZ' ,A' + σZ' ,A' φ and the C's are determined by the initial amounts and by substituting this solution into the differential equation.
  • .In detail, the C's are given by:
    • 1) for Z,A not both equal to Z',A'
      Figure imgb0005
      Figure imgb0006
      (where C's which don't obey the conditions Z' ≤ Z, A'≥A are zero)
      Figure imgb0007
      Figure imgb0008
  • These substitutions are carried out in order of increasing Z and increasing A. Thus the lowest nuclide in a chain, which will occasionally be a bad isotope, has its amount decreased following an exponential curve:
    Figure imgb0009
  • The effective half life for removal is
    Figure imgb0010
  • These effective half lives of the bad nuclides are compared to the natural half life in Table 2. The effec" tive flux is taken to be 1016 neutrons/cm2 sec.
  • Another case of importance is that of a nuclide which has a lower nuclide in the chain with a smaller value of λ. Let us take, for example, a nuclide (Z,A) accompanied by a lighter isotope (Z, A-1) such that λZ,A-1≤λZ,A
  • Then the solution
    Figure imgb0011
    will approach for large t
    Figure imgb0012
    so that the ratio
    Figure imgb0013
  • This constant is evaluated by substitution into the differential equation, and found to be
    Figure imgb0014
  • In the cases considered below, neutron absorption dominates λZ,A and σZ,A » σZ,A-1' so this equilibrium ratio becomes the ratio of cross sections
    Figure imgb0015
  • This establishment of equilibrium also applies to longer chains. This effect is important for Kr 85, Zr93, Pd107, and Sm151, as is discussed below.
  • The transmutations of the 18 bad isotopes have been analyzed for periods of up to about 100,000 hours (about 11 1/2 years) of irradiation in a flux of 1016 neutrons/cm2 sec. From Table 2, one can see that this time period ranges from orders of magnitude more than enough time to remove a nuclide to less than one half-life. The improvement of removal rate over natural decay varies from a few percent to a factor of over 10 .
  • Two types of ideal cases may be considered, one with perfect isotope separation being carried out frequently before and during the separation/irradiation cycles and one with perfect chemical separation being carried out periodically. Clearly, the more separation that can-be accomplished, the more efficient is the transmutation. The isotope separation provides an absolute optimum situation, and provides a measure of the inefficiency of chemical separation. For the case of chemical separation, two possibilities are treated for some waste components. In the first case, it is assumed that there is control over the time between fission and chemical separation. This situation is possible in liquid fission fuel reactors where the fuel and waste may, for example, be continuously cycled without shut-down of the reactor. In the second, the time between fission and separation is assumed long, as for example, in solid fuel fission reactors. The extra control allows one to separate nuclides which would otherwise decay into another element.
  • Table 3 shows the results of the computer analysis for chemical separation and for isotope separation. The two cases of chemical separation are labeled a and b for separation with and without timing respectively. The table is ordered by increasing half life and divided into the first and second groups previously defined in relation to Table 1.
  • A very rough measure of the hazard of nuclear waste is the total amount of each of the two groups of bad nuclide. (This measure neglects differences in biological activity, in ease of storage (i.e., geochemical effects, in half life within a group, and in the nature of the radiation emitted). The waste starts with about 15 atoms per hundred fissions for the low group and 20 atoms of the high group.
  • With isotope separation, after the processing of each nuclide for a length of time somewhat appropriate for the nuclide, but for less than 12 years, 4 atoms of the low group and 2 atoms of the high group remain. If the processing (with isotope separation) were to continue up to 12 years, half the Cs137 (3.1 atoms), a small amount of Sr90 (.14 atoms) and traces of Ru106, Sb125, and Kr would remain in the lower group. Other sizable numbers in the table result from the short time of processing imagined. The high group would contain a small amount of Sn126, an amount of Se depending on its cross section but less than .035 atoms, and a trace of Zr93. All other bad nuclides would be removed. About 32 of the up to 127 neutrons would be used.
  • With chemical separation only there are a number of significant differences. After processing, there are in addition .0014 atoms of Sb125, .06 atoms of Kr85, and .013 atoms of Sm151 remaining in the lower group, and a considerable amount (.5 to .86 atoms) of Zr93 and..035 atoms of Pd 107 remaining in the upper group. The neutron usage has increased from 32 up to 47 or 74 neutrons, from 12 to 20 in the lower group and from 20 to 27 or 55 in the higher group. The 8 extra neutrons in the lower group have been used about 4 for Pm147, and about 1 each for Eu 155 Kr85, and Sm151. In the upper group the extra neutrons have been used largely by Zr , even in case a, and by Cs135 if case b holds. Pd107 has also used up an extra neutron.
  • It is to be noticed that case a of Cs135 (discussed in detail below) is even superior to isotope separation, due to the tiny amount of processing time required.
  • With chemical separation only there is another important consideration. For a number of the elements with bad isotopes, there are stable isotopes with a smaller cross section than the bad isotope. As separation/irradiation goes on, the bad isotope is depleted while the level of stable isotopes remains high. In five cases, listed in Table 4, a significant amount of stable isotopes remain after a reasonable amount of processing. The amount of bad isotope is listed and the number of neutrons that would be wasted in completely transmuting all of the stable isotopes. This amount is most significant for Zr93, even though the more favorable case was chosen (i.e., case a). The ratio of extra neutrons to bad isotope remaining is the largest in the case of Sm151, in which it requires over a thousand neutrons to convert the good Samarium in order to remove one atom of the bad.
  • If the large number of neutrons required are not available, then the remaining amounts of these elements, containing the remaining bad isotope, have to be disposed of, and the bad isotope remains a hazard. As the high neutrons flux exposure goes on, different lots of these elements at different degrees of depletion of the bad isotope may be kept isolated from one another. This process may be accomplished by a spiral-type channel arrangement shown in Figure 2 by the dotted lines in reference to component A.
  • On the other hand, the remaining elements, most notably the large amount of CS137, can have the partially processed part of the element combined with the part of that element freshly separated from the recent fission waste, as indicated by the solid lines in Figure 2.
  • The greatest advantage of isotope separation would occur for zr93, which wastes a large number of neutrons and which has a very significant amount of Zr 93 left with the stable isotopes of Zirconium after a reasonable amount of processing has taken place. Isotope separation is significant for Cesium unless case a is utilized, because of the large number of neutrons needed. Isotope separation is also useful for Sr90 and for the other elements on Table 4 if the amounts remaining are considered objectionable, and depending on the required neutron economy could be useful for those elements which require extra neutrons.
  • Each element was studied by computer runs utilizing the program WASTE shown in the appendix. Perfect chemical separation processing has been assigned for each channel with respect to all elements not originally in the channel.
  • The bad nuclides are discussed in order of increasing atomic number and increasing atomic weight. It is noted that in developing a strategy for each indicidual bad nuclide, there is no interdependency between the individual bad nuclides except in the case of Pr147 and Sm151.
  • Se79
  • The decay/transmutation chain for Se 79 is shown in Figure 7. The thermal neutron absorption cross section for Se79 is shown in Figure 7. The thermal neutron absorption cross section for Se79 is not reported (probably owing to its low abundance) and may be assumed small. Thus one may assume that no significant reduction of this isotope is possible. If however the neutron absorption cross section is found to be significant: the separation/irradiation process may be utilized with Br and Kr removed periodically to enhance neutron economy.
  • Kr85
  • Figure 8 shows the decay/transmutation chain for Kr85. Only about 20% of the A = 85 waste ends up as radio- active Kr85. The remainder ends up as Rb85, because the rapid Bdecay chain passes through an excited isomer of Kr85 which B decays to Rb85. As a result, there is considerably more of the stable isotopes Kr83, Kr84, and Kr86. Kr83 has by far the largest neutron absorption cross section. Kr84 and Kr 86 each have a cross section about 1/20 of Kr 85.
  • When the Kr is subject to the neutron flux Kr83 is converted into Kr84. At this point the ratio of Kr 84 to Kr 85 is about 5. This ratio cannot exceed 20 (the ratio of the cross sections of Kr85 and Kr84). Therefore, after about 75% of the Kr85 has been transmuted, it becomes difficult to convert any more Kr . For every 20 atoms of Kr converted to Kr , only 21 are converted to Kr86. Meanwhile about 30 Kr86,s are transmuted. Thus it takes about 70 neutrons to gain 1 Kr85.
  • The results of the actual circulation are shown in Figure9 to 48,000 hours (somewhat over 5 years) at which time 75% of the Kr85 is gone. At about this time, the natural decay of Kr85 actually removes if faster than continued exposure to neutrons. Only isotope separation would improve matters. Figure 9 also shows the removal of Kr85 as compared to its natural decay. Also shown are the average and marginal usage of neutrons showing the effects to Kr83 at very small times and Kr84 at large times. Different scales are used for amounts and neutron usage.
  • Thus is is reasonable to reduce Kr85 to a level 2 or 3 times lower than natural decay would give, and no further except with isotope separation. In order to conserve neutrons it was assumed that all the decay/transmutation products, i.e., Rb and Sr were completely separated from Kr after each irradiation step was completed. The gas Kr may be readily separated from these solid products.
  • Sr90
  • The decay/transmutation chain for Sr90 is also shown in Figure 8. Sr90 is transmuted according to the exponential law, since the only other isotope of Strontium in the waste is stable Sr88 which transmutes to Sr89 with a very small cross section. Sr89 is initially present in the waste (as well as being produced from Sr88), but it decays with a half life of 1250 hours, short compared to the relevant time scale for the transmutation of Sr90.
  • The program WASTE was utilized with chemical processing every 3000 hours. No indication of undesirable effects of the build-up of Yttrium and Zirconium were noted. Clearly a much less frequent chemical processing for separation of Y and Zr from Sr would suffice. Only 1.06 neutrons are required for each transmutation of the first 96% of the Sr90. The effective half life of Sr90 in a flux of 1016 neutrons per square cm per second is 2-1/4 years.
  • Zr93
  • More of the nuclear waste is Zirconium (15%) than any other single element. The presence of many stable isotopes of Zirconium, in addition to the bad isotope Zr93, make the removal of this isotope by transmutation difficult. The stable isotopes in the waste are Zr91, Zr92, Zr94, and 96 93 Zr . Although Zr has a larger neutron absorption cross section than any of the stable isotopes, it is not larger enough to make transmutation easy. Figure 10 shows a portion of the decay/transmutation chain including Zr93.
  • Two possibilities for the treatment of Zr93 are considered. In the more favorable case, the initial chemical separation is carried out in a time short compared to two months after the fission process. Such is the case, for example, in a liquid fuel reactor with continuous processing for wastes. In this case, the Yttrium is separated from the Zirconium. The Y91, with a half life of about two months, decays into stable Zr91, which therefore is isolated from the 93 92 93 94 95 96 Zr93. The Zr92, Zr93, Zr94, Zr 95 and Zr96 are then allowed to stand, allowing the Zr95 to decay (with a half life also of about two months).
  • The results presented for Zr 93 labelled as cas a assume the ideal situation of no Zr91 in the Zirconium to be irradiated by the neutrons. In this case, the Zr whiche starts at the level of 6.36 atoms per hundred fissions, is irradiated for about 6 years resulting in about 92% net removal of the Zr93, at a cost of 12 neutrons, or a little worse than 2 neutrons per atom removed. Further irradiation accomplished little, because at this point the transmutation of Zr93 is approaching equilibrium with the transmutation of Zr92 into Zr93, and there are significant amounts of Zr94 and Zr96, as well as Zr92 competing for the transmutation neutrons. The removal of Zr93 is shown in Figure 11.
  • In the less favorable case, labelled b in the results the Zr91 is included. After 50,000 hours (about 6 years) the Zr91 has addes an extra 6% of the original Zr93 by the sequential transmutation chain, Zr91 → Zr92→ Zr93 atom removed. In both cases, neutron economy is enhanced by periodically separating Zr from Nb and Mo.
  • It is clear that isotope separation would help greatly for Zr93. The exponential removal curve for pure Zr93 is compared to the curves for chemical separation in Figure 11. Ater 50,000 hours almost 99% of the Zr93 is transmuted.
  • Tc99
  • Tc99, whose decay/transmutation chain is shown in Figure 12, provides one of the most favorable cases for transmutation. It has a reasonably large cross section for neutron absorption and there is only the single isotope, Tc99, in the waste. Therefore the removal follows an exponential curve (with an effective half life of 42 days). After chemical processing, all the Tc can be combined, since it is all Tc99. With chemical processing ecery 300 hours, the neutron usage is 1.03 neutrons per transmutation. The extra 3% comes from absorption in Ru100 which builds up for the 300 hours.
  • Ru106
  • Ru106, whose decay/transmutation chain is shown in Figure 13, has a half life of 1.01 years, just above the cutoff of 1 year. It requires 33.4 years to decay to half the activity of U238. It has a very small neutron absorption cross section, 146 barns, requiring an exposure to neutrons for 31.4 years to reduce the activity to the same level. The saving of 2 years is not deemed worth the trouble and expense of cycling and processing. Therefore Ru106 may be treated as a short-lived isotope, storing it for at least 33-1/2 years before allowing it to enter the environment.
  • Pd107
  • The decay/transmutation chain for Pd107 is shown in Figure 13. There is not much Pd107 in the waste since it is on the high side of the lighter bump in the fission yield curve. Pd105, with an atomic weight smaller by only 2, has 6 times the fission yield. Ru106 has an intermediate yield, and decays to Pd106 (in two stept) with a half life of 1 year. Ruthenium is assumed to be separated from the Palladium before a significant amount of it has been allowed to decay (if processing occurs within half a year after fission, the results are not substantially modified).
  • The Pd105 has a cross section 40% larger than Pd107, which when multiplied by the factor of 6 in yield gives a conversion rate 8.4 times that of Pd107. Pd107 transmuted to Pd108, which, with a roughly comparable cross section, converts to Pd109 which rapidly decays. Thus, in the early stages of transmutation it takes over 10 neutrons for each transmutation of a Pd107 atom.
  • Later, the concentration of Pd106 builds up, approaching an equilibrium value of about 40 times the amount of Pd107, since its cross section is 40 times smaller. At equilibrium 40 atoms of Pd106 convert to Pd109 , requiring 120 neutrons, for every net Pd107 removed. The average neutron use per Pd removed approaches 4x6+2 = 26 for each 6 atoms of Pd105 and one atom of Pd107 converted to Pd 109
  • In an actual example calculation 78% of the Pd107 was removed in 9000 hours, at a cost of about 12 neutrons for each atom of Pd107 removed. Since the initial amount was small, this corresponds to, for example, a level of Cs135 after removal of 99-1/2% of the initial amount.
  • Neutron economy would dictate removal of Pd from Ag and Cd prior to recycling into each new irradiation step. Sn 126 and Sb 125
  • The decay/transmutation chain for Sn 126 and Sb125 are shown in Figure 14. These isotopes occur at the minimum of the yield curve, and are present in very small amounts. As a result, neutron economy is not of paramount importance and the products I and Te need not generally be separated. They are treated together because exposure of tin to neutrons produces Sb125. The cross section for Sn 126 is very small, so transmutation is very slow. After about 12 years in a flux of 10 16 neutrons/cm2 sec., one third of the original Sn126 still remains. However, this corresponds to .3% of any one of the five most common bad isotopes. Sb125 is easily removed. 129
  • I129 (Figure 15) is removed following an exponential curve, since I128 is highly unstable. The effective half life of I 129 in a flux of 1016 neutron/cm2 sec., is about a month. The neutron use does not exceed 1.2 neutrons per I 129 atom transmuted, as the I129 is accompanied by 1/5 as much I 127. In the early stages, the situation is even more favorable since the cross section for I127 is smaller. After 3000 hours, the average use was 1.1 neutrons per transmutation, as only about half of the I 127 was removed.
  • The enrichment of I127 relative of I129 probably is not significant enough, due to the small amount involved, to make it worthwhile keeping the iodine already processed separate from the iodine freshly produced from fission.
  • The results for a 3000 hour processing run are presented in Table 3, but it is to be understood that exponential removal continues indefinitely.
  • Iodine may readily be separated from the fission waste and is thus a very favorable element for waste transmutation.
  • Cs 134, Cs135 and Cs137
  • Cs135 and Cs137 are somewhat separate problems, and are discussed separately. Cs 134 is not a direct fission product and therefore occurs in small amounts in the waste. It has a large cross section and is easily removed in the treatment of Cs135 and Cs137. Figure 16 shows a portion of the decay/transmutation chain including Cesium.
  • The major problem with the treatment of Cs135 is the large amount (6.75 atoms/100 fissions) of stable Cs133 in the waste. Cs133 has a considerably higher neutron absorption cross section than Cs135, and must absorp 3 neutrons before again becoming a stable nuclide. The chain is Cs133 → Cs135 → Cs136 → Ba136.
  • It is noted, however, that the cesium in the waste comes from βdecay of the inert gas Xenon. Xe133 has a half life of over 5 days, and Xe135 has a half life of over 9 hours. Xe135 has an extremely high neutron absorption cross section (3x106 barns) and stable Xe 136 has a very small cross section (.16 barns). Stable Xe 134 also has a rather small cross section (1.73 barns).
  • If the Xenon is separated in a time small compared to 5 days after fission, and especially if it can be separated in a time small compared to 9 hours, Cesium may be efficiently treated. A liquid fuel reactor would clearly be desirable in achieving these short processing times, since the processing may be continuous.
  • As soon as Xenon is separated out, it is exposed to a high neutron flux for a short time. At 1016 neutrons/cm2 sec., the optimum time is 11 minutes. In the example of Tabel 3, 20 minutes was used. After this irradiation the Xenon is removed from the flux and stored for, say,two months for the Xe133 to decay (this is about 30 half lives of Xe133). After this, the Xenon left is not radioactive. There may be a further separation of the Cesium produced in the first two hours after fission. Thus there are three, possibly four, places in which Cesium is produced. The Cesium produced before separation consists of some or most of the Cs137 and a small amount of CS135 and Cs133. The amounts depend on the time before separation. The Cesium produced during the irradiation is some or most of the Cs137, and a small amount of Cs135 and Cs133. For the first two hours after fission, Cs137 is produced, and it might be desirable to keep it with the Cesium produced in the first two steps. After 2 hours, most of the Cs133 is produced. This Cs133 would not be subject to further irradiation The amount of Cs135 that is contained in with this Cs133 is 4.4 x 10-6 atoms per 100 fissions (22 parts per billion of the waste), coming from the equilibrium between Xe 134 and Xe135.
  • Figure 17 shows the amount of Cs133 and Cs135 produced up to end of the time of irradiation as a function of the time of separation. If, for example, separation is accomplished in 6 minutes, there will be 0.055 atoms of Cs135 per 100 fissions. In the first two hours after irradiation 0.08 atoms of Cs133 per 100 fissions out of a total of 6.75 are produced.
  • The results labeled a in Table 3 correspond to no further treatment of the Cs135, although, of course, it would be treated if the Cs137 is treated. The results assume immediate separation of the Xenon.
  • 1 In cases when the Xenon cannot be separated out rapidly (solid fuel reactors), much of the Xe135 is not transmitted to Xe136, but decays to Cesium which must be treated. These results are shown in Figure 18, and as case b in Table 3.
  • As can be seen, the time scale is long and the neutron usage is extremely large, costing 20 neutrons (per 100 fissions) to convert the stable Cs133 to Ba136. Isotope separation would clearly be highly desirable. Figure 18 shows the following sequence of events:
    • 1. Cs134 relatively rapidly builds up from the transmutation of Cs133, until after about 500 hours it is in equilibrium with Cs 133
    • 2. After about 100 hours enough Cs134 has built up that the amount of Cs135 actually increases:
    • 3. After 2000 hours the Cs133 and Cs134) is mostly depleted, and the Cs135 starts being removed following an exponential curve;
    • 4. At about 2700 hours, the amount of Cs135 xis back to where it started.
    • 5. The amount of Cs135 lags 2900 hours (4 months) behind where it would be had there been no Cs133 in the waste to be irradiated.
  • If the Cs133 is handled by transmuting Xe the remainder of the Cs135 can be removed following curves similar to case b, but about 100 times lower. The extra neutron usage will also be about 100 times smaller. If the separation time in case a is 2 to 100 hours, a situation intermediate between case a and case b results.
  • Cs137 has the smallest neutron absorption cross section of any of the bad nuclides (with the possible exception of Se79). Irradiation in a flux fo 1016 neutrons/ cm2sec. only brings the effective half life to 12 years, compared to 30 years for natural decay. Aside from a small amount of Cs137 generated from Cs135 → Cs136 → Cs157, Cs137 removal follows an exponentialn curve (most Cs136 decays to Ba136).
  • Since the Cesium becomes essentially pure Cs137 as the processing continues, there is no need to segregate the oid andnew Cesium if Cs137 is to be treated.
  • The modest gain in removal rate in Cs137 might make it not worthwhile to treat it beyond what is needed for Cs135 removal, unless a flux even higher than 1016 neutrons/cm2 sec., is utilized. Neutron economy is improved by separation of Cs from all other products, i.e. Ba,La, Ce, etc.
  • Pm147
  • Pm147 (figure 19) is the lightest isotope of Promethium in the waste, and the only one with a large half life. It is transmuted following an exponential curve with an effective half life of 4-1/3 days in a flux of 1016 neutrons/cm sec.
  • The difficulty in removing Pm147 concerns neutron economy. In any flux which gives a transmutation rate larger than the natural decay, most of the Pm147 ends up as Sm150, mostly by the chain Pm147 → Pm148 → Pm149 → Sm149 →Sm150. Thus it costs 3 neutrons per Pm147 atom transmuted.
  • There is also a small amount of the bad isotope Sm151 created from the Sm150, the amount depending on the frequency of chemical separation of the Samarium from the Promethium (the Samarium is then not exposed to any more neutrons). In the example of Table 3, chemical processing was assumed to occur every 2 hours. The amount of Sm 151 produced iscomparable to the amount of Sm151 left after the irradiation of the Samarium waste. It is not feasible, without isotope separation, to transmute this Sm151
  • Since Pm147 with a half life of 2.6 years is rendered essentially harmless by storage of about 85 years, while the Sm151 produced requires 1900 years to reduce it to the same low level of activity, it may be better not to attempt to transmute the Pm147. However, if higher level are considered acceptable, the decrease of 2.3 atoms of Pm147 to .005 atoms of Sm151 is significant.
  • Sm151
  • The Sm151(figure 19) is accompanied by a larger amount of Sm 149 Sm151 has a large neutron absorption cross section (1.4 x 104 barns) but Sm 149 has an even larger cross section by nearly a factor of five.
  • Therefore, a Samarium is exposed to the neutrons, the first thing to happen is the conversion of Sm149. This can be seen on figure 20 by the large neutron usage in the first two hours of irradiation. The next thing to happen is the transmutation of most of the Sm151. The cost in neutrons rises during this period from a minimum at around 3 hours into the irradiation. This rise in neutron usage is due to the competition of neutron absorption in Sm152 and Sm150, and the Sm151 being produced from Sm150. Finally, the Sm151 comes into equilibrium with the Sm150 at a level Sm151/Sm150= σ150151 ≈ 1/40. At this point, about 98% of the initial amount of Sm151 is removed. Equilibrium is nearly obtained after about 15 hours, as seen in figure 20. Further irradiation is extremely costly in neutron usage even though there is such a small amount of Sm151 remaining. Moreover, the Sm151 resulting from the treatment of Promethium is at roughly the same level. The treatment of this other Samarium would actually cause an increase in the amount of Sm151, since the Sm151/Sm150 ratio is well below 1/140. Thus, without isotope separation, (or an extremely copious supply of neutrons) a reduction of Sm151 to about .013 atom per 100 fissions is the best that can be achieved. Neutron economy may be enhanced primarily by separation of Eu products.
  • Eu152 ,Eu154 ,Eu155
  • Europium (figure 19 & 21) is one of the heaviest elements in the waste, and occurs in small amounts. Eu152 and Eu154 do not occur directly as fission products. What little Eu152 does occur will be rapidly transmuted while the Eu155 is being removed, as wil the Eu151 coming from the Sm 151 that decayed before it was transmuted.
  • In processing the Europiu, it need not be separated from the Samarium while the Samarium is being processed, as there will be small amounts of radioactive Europium produced in the treatment of Sm151, which should be included with the fission-produced Eu155.
  • Transmutation of Eu155 per se is very simple, as indicated by the "isotope separation" columns of table 3. However, the waste contains some Eu153, which is converted to radioactive Eu154. Therefore, in order to remove the Eu 155 it is necessary to convert the Eu153 by the chain
    Figure imgb0016
  • There is 5 times as much Eu153 as Eu155, and it requires 5 neutrons for conversion to Gd158 leading to 26 ½ neutrons per atom of Eu155 removed.
  • If the flux were 10-30 times smaller, the Eu 156 would have time to decay, terminating the chain at Gd, saving up to 40% of the neutrons.
  • Fig.22 shows the time development of the amounts of Eu154 and Eu 155. For the first 15 hours or so, the initial Eu155 is rapidly transmuted away, while the Eu154 builds up almost as fast as the Eu155 is removed. After that, the Eu154 continues to build up while it, in turn, transmutes to Eu155. . After about 60 hours the Eu154 and Eu155 are in equilibrium with the remaining Eu153 and then are removed at a rate determined by the Eu153 cross section.
  • In the processing, all isotopes of Europium are removed. Therefore, no harm is caused by combining the already-processed Europium with fresh Eu.
  • ACTINIDES
  • The amounts and composition of the actinides depends on the parameters of the reactor system such as the enrichment of the Uranium and the integrated flux to which it has beenexposed. We consider four components of the actinides produced from U238 and U 235 by neutron absorption, which may conincide with the components in the transmutation system. These components are:
    • 1. U236
    • 2. Np237
    • 3. Fresh plutonium
    • 4. Spent plutonium and trans-olutonium actinides.
  • Fifteen percent of the U 235 on absorbing a neutron does not fission but produces U236. This U236 would be only moderately expensive in neutrons to transmute except that it is mixed in with all the U238 in the spent fuel.
  • It is impossible from the point of view of neutron economy to put the U238 in the high flux region. If the U236 produced from all U 235 by neutron irradiation is mixed in with the amount of U238 accompanying that much U 235 in natural uranium, the radioactivity is double that of U238. Therefore, U236 does not pose a serious hazard if combined with the U238.
  • Some of the U236 will absorb a neutron, giving the transmutation chain
    Figure imgb0017
  • If this Np237 is exposed to as high a flux as possible , it-first transmutes to Np238 which then fissions if it absorbs a neutron or decays to Pu238. The fissioning is preferable on the grounds of neutron economy.
  • U238, if it absorbs a neutron, becomes Pu239 This plutonium (as well as the Pu238 discussed above) is, on separation, used as a fissionable substance. In thermal fission, 3/4 is fissioned and 1/4 becomes Pu240. The Pu240 absorbs a neutron becoming Pu241, Three-fourths of Pu241 fissions and 1/4 becomes Pu242.
  • Pu242 and heavier isotopes are not fissionable with high probability and form part of the heavy actinide waste. By sequential neutron absorption, these eventually lead to fission. Fissionable isotopes include Cm245, Cm247, Bk250, Cf249. Vg251, and Es254. Although the number of neutrons required per atom of pu242 is large, the very small quantities involved makes the neutron usage not have a serious effect on the total neutron economy. This is consistent with the conclusion of earlier studies that actinides can be reduced by transmutation.
  • The neutron economy is approximately a net loss of one neutron for each atom of Np237 (including the absorption on U 236) and approximately a balance (a small net loss) for each atom of U238 transmuted. In addition, the fission wastes from Plutonium and other actinides increase the amount of fission wastes that must be processed by the excess neutrons from the fission of U235.
  • Figure imgb0018
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    Figure imgb0048

Claims (17)

1. A method of decreasing the amount of relatively long lived fission products of radioactive waste materials in excess of that due to their natural radioactive decay by producing relatively short lived radioactive nuclides and stable nuclides from said relatively long lived fission products comprising the steps of:
a) separating said fission products into at least (1) a plurality of components, each component having at least one relatively long lived fission product nuclide and (2) relatively short lived radioactive nuclides and stable nuclides,
b) storing at least some of said relatively short lived radioactive nuclides and stable nuclides,
c) exposing at least some of said components to a high thermal neutron flux for inducing transformation of at least some of said relatively long lived fission product nuclides to produce relatively short lived radioactive nuclides and stable nuclides,
d) removing each exposed component and said produced relatively short lived radioactive nuclides and stable nuclides from said high thermal neutron flux,
e) separating said components from at least some of said produced short lived radioactive nuclides and stable nuclides, and
f) repeating steps b) - e) at least one time; and
g) storing said components after they have reached a reduced level of radioactivity over their natural decay.
2. A method as recited in Claim 1, wherein a component comprises Se79.
3. A method as recited in Claim 1, wherein a component comprises Krypton.
4. A method as recited in Claim 1, wherein a component comprises Strontium.
5. A method as recited in Claim 1, wherein a component comprises Zr93.
6. A method as recited in Claim 1, wherein a component comprises Ic99.
7. A method as recited in Claim 1, wherein a component comprises Pd107.
8. A method as recited in Claim 1, wherein a component comprises Sn126.
9. A method as recited in Claim 1, wherein a component comprises Sb125.
10. A method as recited in Claim 1, wherein a component comprises Iodine.
11. A method as recited in Claim 1, further comprising the step of separating the gas Xenon from the fission products and exposing same to said high thermal neutron flux to prevent the formation of Cs 135.
12. A method as recited in Claim 1, wherein a component comprises Cs135
13. A method as recited in Claim 1, wherein a component comprises Cs137.
14. A method as recited in Claim 1, wherein a component comprises Pm147.
15. A method as recited in Claim 1, wherein a component comprises Sm151.
16. A method as recited in Claim 1, wherein a component comprises Europium.
17. A method as recited in Claim 1, wherein a component comprises at least one actinide.
EP80201147A 1979-12-05 1980-12-03 Method for net decrease of hazardous radioactive nuclear waste materials Expired EP0030404B1 (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1985004752A1 (en) * 1984-04-09 1985-10-24 Gerrit Berdinus Engelen Method for systematic transformation of nuclides
GB2246467A (en) * 1990-07-13 1992-01-29 Doryokuro Kakunenryo Transmutation treatment of radioactive wastes
WO1994017532A1 (en) * 1993-01-18 1994-08-04 Eremeev Igor P Process for effecting the transmutation of isotopes
ITCO20130066A1 (en) * 2013-12-16 2015-06-17 Wow Technology S P A METHOD TO TREAT AN AQUEOUS SOLUTION / DISPERSION CONTAINING AT LEAST A RADIOACTIVE SUBSTANCE AND PLANTS THAT REALIZE IT
EP3273446A4 (en) * 2015-03-20 2018-11-21 Riken Radioactive waste processing method

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB802971A (en) * 1956-01-27 1958-10-15 Louis Verschraeghen Process for the destruction of radio-active residues
DE2249429A1 (en) * 1972-10-09 1974-04-18 Kernforschung Gmbh Ges Fuer Fuel element fission product decay - by further irradiation in reactor core

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB802971A (en) * 1956-01-27 1958-10-15 Louis Verschraeghen Process for the destruction of radio-active residues
DE2249429A1 (en) * 1972-10-09 1974-04-18 Kernforschung Gmbh Ges Fuer Fuel element fission product decay - by further irradiation in reactor core

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO1985004752A1 (en) * 1984-04-09 1985-10-24 Gerrit Berdinus Engelen Method for systematic transformation of nuclides
GB2246467A (en) * 1990-07-13 1992-01-29 Doryokuro Kakunenryo Transmutation treatment of radioactive wastes
DE4123145A1 (en) * 1990-07-13 1992-02-06 Doryokuro Kakunenryo TRANSMUTATION TREATMENT OF RADIOACTIVE WASTE
FR2665570A1 (en) * 1990-07-13 1992-02-07 Doryokuro Kakunenryo TRANSMUTATION TREATMENT OF RADIOACTIVE WASTE.
GB2246467B (en) * 1990-07-13 1994-05-11 Doryokuro Kakunenryo Transmutation treatment of radioactive wastes
DE4123145C2 (en) * 1990-07-13 2003-01-30 Japan Nuclear Cycle Dev I Toka Transmutation treatment of radioactive waste
WO1994017532A1 (en) * 1993-01-18 1994-08-04 Eremeev Igor P Process for effecting the transmutation of isotopes
FR2702591A1 (en) * 1993-01-18 1994-09-16 Eremeev Igor P A method of transmutation of isotopes
ITCO20130066A1 (en) * 2013-12-16 2015-06-17 Wow Technology S P A METHOD TO TREAT AN AQUEOUS SOLUTION / DISPERSION CONTAINING AT LEAST A RADIOACTIVE SUBSTANCE AND PLANTS THAT REALIZE IT
EP3273446A4 (en) * 2015-03-20 2018-11-21 Riken Radioactive waste processing method
US10629316B2 (en) 2015-03-20 2020-04-21 Riken Radioactive waste processing method

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