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Simulation of Absorbed Dose Distribution In Space Materials

Published online by Cambridge University Press:  01 February 2011

Boris A. Briskman*
Affiliation:
Karpov Institute of Physical Chemistry, Obninsk, 249033, RUSSIA
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Abstract

The problems of absorbed dose distribution simulation at on-ground space material tests are discussed. Several approaches to such simulation, oriented to increase the test adequacy and economy, are analyzed. Sometimes, it is possible to use quantitative criteria of absorbed dose distribution depending on the specific space vehicle orbit. The assessment of reliable simulation of the radiation spectrum may be made, for example, by introducing a special numerical characteristic of the depth dose profile in a material - depth dose criterion. For this purpose, it is recommended to use the ratio of the exponent index of the depth dose profile (μ) to the density of the material (ρ). In the simplest form, the depth dose profile can be represented as a sum of two exponents. The first depth dose profile applies to a near-the-surface layer of 5 to 10 μm in thickness, and the second to a layer of from 10 μm up to, as a minimum, 100 μm in thickness. The reference values of μ/ρ for typical spectra of ionizing radiation are calculated.

Type
Research Article
Copyright
Copyright © Materials Research Society 2005

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References

REFERENCES

1. Briskman, B.A., Toupikov, V.I., and Lesnovsky, E.N., in Materials in a Space Environment, (Proc. of the 7th Intern. Symp. ONERA, Toulouse, France, 1997) pp. 537542 Google Scholar
2. Briskman, B.A. and Borson, E.N., in The Changing Testing Paradigm, (Proc. of the 20th Space Simulation Conference. NASA/CR-1998–208598, Annapolis, MD, October 27–29, 1998) pp. 187200 Google Scholar
3. Toupikov, V. I., Van Eesbeek, M., Khatipov, S.A., and Stepanov, V.F., in Methodologies for Ground Simulation of the Space Environment, (Proc. The Workshop, Southhampton, Great Britain, 1996) p. 1116 Google Scholar
4. Wilski, H., Rad. Phys. Chem., 29, 1 (1987)Google Scholar
5. Briskman, B.A., Sichkar, V.P., and Kras'ko, L.B., Chemistry of High Energy, 27, 8 (1993)Google Scholar
6. Briskman, B.A., Klinshpont, E.R., Stepanov, V.F., and Tlebaev, K.B., AIAA J. of Spacecrafts and Rockets, 41, 360 (2004)Google Scholar
7. Briskman, B., Belyakov, A., Klinshpont, E.R., Stepanov, V.F., Shavarin, Yu., Borson, E., Novikov, L., and Makletsov, A., High Performance Polymers, 13, 1 (2001)Google Scholar
8. Bourrieau, Y., Paillous, A.. in Space Materials in Space Environment, (Proc. ESA SP-145, 1979) pp. 227245 Google Scholar
9. Marco, J., Paillous, A., and Gourmelon, G., in Materials in a Space Environment, (Proc. of the 6th Intern. Symp. ESTEC, Noordwijk, The Netherlands, 1994) pp. 7783 Google Scholar
10. Paillous, A., Pailler, C., in Materials in a Space Environment, (Proc. of the 6th Intern. Symp. ESTEC, Noordwijk, The Netherlands, 1994) pp. 95102 Google Scholar
11. Tenditnyi, A., Smirnov-Vasiliev, K.G., Yevkin, I.V., and Mironovich, V.V., in Materials in a Space Environment, (Proc. of the 6th Intern. Symp. ESTEC, Noordwijk, The Netherlands, 1994), pp. 113121 Google Scholar
12. Kozlov, L.V., “Simulation of Spacecraft and Space Environment Heat Mode”. Ed. Petrov, G.I., (M., “Mashinostroenie1971) pp. 1382 Google Scholar
13. Akishin, A.I., Teplov, I.B., Physics and chemistry of material treating, 3, 47 (1992)Google Scholar
14. Haruvy, Y., Rad. Phys. Chem., 35, 204 (1990)Google Scholar
15. Akatov, Yu.A., e.a. Nucl. Tracks Radiat. Meas., 17, 105 (1990)Google Scholar
16. Briskman, B., Belyakov, A., Klinshpont, E., Stepanov, V., Shavarin, Yu., Borson, E., Novikov, L., and Makletsov, A., in Materials in a Space Environment (Proc. of the 8th Intern. Symp.) and Protection of Materials and Structures from the LEO Space Environment (Proc. of the 5th Intern. Conf.), Arcachon, France, 2000 Google Scholar
17. Bol'bit, N.M., Taraban, V.B., Klinshpont, E.R., and Milinchuk, V.K., in Materials in a Space Environment (Proc. of the 6th Intern. Symp., ESTEC, Noordwijk, The Netherlands, 1994) pp. 5970 Google Scholar