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The Behavior of Nuclear Fuel in First Days of the Chernobyl Accident

Published online by Cambridge University Press:  03 September 2012

B. E. Burakov ,
E. B. Anderson ,
S. I. Shabalev ,
E. E. Strykanova ,
S. V. Ushakov ,
M. Trotabas ,
J-Y. Blanc ,
P. Winter  and
J. Duco
B. E. Burakov
Affiliation:
V.G. Khlopin Radium Institute, 28, 2nd Murinsky ave., 194021, St. Petersburg, Russia
E. B. Anderson
Affiliation:
V.G. Khlopin Radium Institute, 28, 2nd Murinsky ave., 194021, St. Petersburg, Russia
S. I. Shabalev
Affiliation:
V.G. Khlopin Radium Institute, 28, 2nd Murinsky ave., 194021, St. Petersburg, Russia
E. E. Strykanova
Affiliation:
V.G. Khlopin Radium Institute, 28, 2nd Murinsky ave., 194021, St. Petersburg, Russia
S. V. Ushakov
Affiliation:
V.G. Khlopin Radium Institute, 28, 2nd Murinsky ave., 194021, St. Petersburg, Russia
M. Trotabas
Affiliation:
Center D'Etudes de Saclay, 91191 Gif-Sur, Yvette CEDEX, France
J-Y. Blanc
Affiliation:
Center D'Etudes de Saclay, 91191 Gif-Sur, Yvette CEDEX, France
P. Winter
Affiliation:
Center D'Etudes de Saclay, 91191 Gif-Sur, Yvette CEDEX, France
J. Duco
Affiliation:
IPSN, 60–68 ave. du General Ledere, BP6–92265 Fontenay-Aux-Roses CEDEX, France
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Abstract

Various types of Chernobyl fuel containing masses named black “lava”, brown “lava”, porous “ceramic” and “hot” particles that formed during first days of the accident at the Chernobyl Nuclear Power Plant 4th Unit were studied by methods of optical and electron microscopy, microprobe and x-ray diffraction. Data about their chemical, phase and radionuclide composition are summarized. The products of interaction between fuel, zircaloy and concrete, produced under experiments in laboratory were examined for comparison with samples of Chernobyl “lava” and “hot” particles. The behavior of nuclear fuel in first days of the Chernobyl accident was a three-stage process. The first stage occurred before the moment of the Chernobyl explosion and was exceptionally short-lasting, perhaps, less than a few seconds. It was characterized by reaching a high temperature, ≥2600 °C, in the epicenter of accident and formation of a Zr-U-O melt in a local part of the core, which is estimated to be not more than 30% of whole core volume. The second stage lasted for about 6 days since the explosion, during which there was interaction between uranium products of the destroyed reactor: UOx, UOx with Zr, Zr-U-O, with the environment and silicate structural materials of the 4th Unit. The third stage, after 6 days involved the process of final formation of the radioactive silicate melt or Chernobyl “lava” at one of the sections of the destroyed 4th Unit. During this stage the melt's lamination occurred, followed by a break-through of the “lava” reservoir on the 11 th day of the accident and penetration of the “lava” into space under the reactor.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 465: Symposium II – Scienfific Basis for Nuclear Waste Management XX , 1996 , 1297
Copyright
Copyright © Materials Research Society 1997

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References

REFERENCES

1. At. Energ. 61, p. 301 (1986) (in Russian).Google Scholar
2. Nuclear News 29, p. 59 (1986).Google Scholar
3. Publication series on safety N 75-INSAG-l, Proceedings of Conference on Studies of Causes and Consequences of Chernobyl Accident. IAEA, STI/PUB/740, ISB N-92–0–423088–6, Wien (1988).Google Scholar
4. Devell, L., Tovedal, H., Bergström, U., Appelgren, A., Chyssler, J., Andersson, L., Nature 321, (1986) p. 192 Google Scholar
5. Schubert, P., Behrend, U., Radiochimica Acta 41, p. 149155 (1987)Google Scholar
6. Bogatov, S.A., Borovoy, A.A., Dubasov, Yu.V., Lomonosov, V.V. About forms of the fuel release in the accident at the Chernobyl NPP. Preprint IAE-4952, Moscow (1989) (in Russian).Google Scholar
7. Borovoy, A.A. Inside and outside the “Sarcofagus”. Preprint KE IAE, Chernobyl (1990). (in Russian).Google Scholar
8. Bogatov, S.A., Borovoy, A.A., Dvoretskiy, V.I., Elesin, L.A., Isaev, N.V., Lomonosov, V.V., Lebedeva, L.I., Matveev, I.V., Nikitin, V.N., Obukhova, L.A., Semin, I.A., Simirskiy, Yu.N., An investigation of the most radiologically hazardous nuclides in various forms of the fuel release of the Chernobyl accident. Preprint IAE-5022/3, Moscow (1990). (in Russian).Google Scholar
9. Piasecki, E., Jaracz, P., Mirowski, S., J. of Radioanalytical and Nuclear Chemistry, Articles 141, 2, p. 221259 (1990)Google Scholar
10. Bogatov, S.A., Borovoy, A.A. Preprint IAE-5344/3, Moscow (1991). (in Russian).Google Scholar
11. Anderson, E.B., Burakov, B.E., Pazukhin, E.M., Radiokhimia 5 (1992) p. 139 (in Russian).Google Scholar
12. Khitrov, L.M., Cherkezian, V.O., Rumiantsev, O.V., Geochemistry 7 (1993), p. 963. (in Russian).Google Scholar
13. Petriaev, E.P., Leynova, S.L., Sokolik, G.A., Danil'chenko, E.M., Duksina, V.V., Geochemistry 7, (1993), p. 930 (in Russian).Google Scholar
14. Burakov, B.E., Anderson, E.B., Galkin, B.Ya., Pazukhin, E.M., Shabalev, S.I., Radiochimica Acta 65, p. 199202 (1994).Google Scholar
15. Borovoy, A.A., Galkin, B.Ya., Krinitsyn, A.P., Markushev, V.M., Pazukhin, E.M., Kheruvimov, A.N., Checherov, K.P., New-formed products of the interaction of fuel with structural materials of the 4th unit of the Chernobyl NPP, Radiochem. 32, p. 103113 (1990).Google Scholar
16. Borovoy, A.A., Ibraimov, G.D., Ogorodnik, S.S., Popov, V.D., Checherov, K.P. The state of the ChNPP 4th unit and nuclear fuel being in it (by results of investigations of 1988–1989). Preprint KE IAE. Chernobyl (1990). (in Russian).Google Scholar
17. Kiselev, A.N., Nenagliadov, A.Yu., Surin, A.I., Checherov, K.P., Preprint IAE-5533/3, Moscow (1992). (in Russian).Google Scholar
18. Krivokhatskiy, A.S., Savonenkov, V.G. Classification of radioactive man-made products from debris of 4th Unit of the Chernobyl nuclear power plant. Preprint RI-216, Ts'NII atominform, (1990). (in Russian).Google Scholar
19. Anderson, E.B., Burakov, B.E., Pazukhin, E.M. Did the fuel of the 4th Unit of Chernobyl NPP melt? Radiochem. 5 (1992). (in Russian).Google Scholar
20. Anderson, E.B., Burakov, B.E., Pazukhin, E.M. High uranium zircon (Zr,U)SiO4 from “Chernobyl lavas”. Radiochimica Acta 60, p. 149 (1993).Google Scholar
21. Burakov, B.E. in Proceedings of international conference SAFEWASTE'93 2, (13–18/06/1993, Avignon, (FRANCE)) p. 1928.Google Scholar
22. Trotabas, M., Blanc, J-Y., Burakov, B., Anderson, E., Duco, J. Examination of Chernobyl samples, impact on the accident scenario understanding. Report IPSN/93/02 (1993), DMT/92/309, RI -1–63/92 (1993).Google Scholar
23. Report of the US Department of Energy's Team analyses of the Chernobyl atomic energy station accident sequence. DOE/NE-0076, DE 87 003614, Washington (1986).Google Scholar
24. Gol'tsova, N.I., Abaturov, N.I. in Eurochernobyl-2.Materials of the international conference. (Kiev, 1992), p. 155 (in Russian).Google Scholar
25. Skokan, A., Proc. on Thermal Nuclear Reactor Safety, KfK-3880/2, p. 10351041. (1984)Google Scholar
26. Kanno, Y., J. Mater. Sci., 24 (1989) p. 2415 Google Scholar
27. Pena, P., de Aza, S., J. of Mater. Sci., 15 (1984) p. 135142.Google Scholar
28. O'Donoghue, M.A. J. of Gemology 3, vol. XV,, (1976) p. 119124.Google Scholar
29. Wanklyn, B.M., J. Cryst. Growth 37, 1 (1977) p. 5156 Google Scholar
30. Synthesis of minerals. v. 2, Moscow: “Nedra”, 1987. (in Russian).Google Scholar
31. Pakhomov, S.A., Krivochatskiy, K.S., Sokolov, I.L., Radiochem. 6, (1991), p. 125. (in Russian)Google Scholar
32. Pazukhin, E.M., Radiochem. 36, iss. 2, (1994), p. 97142. (in Russian).Google Scholar