Testing the Shelf-Life of Nuclear Reactors
Researchers have devised a quick way to test
the structural materials used to build nuclear reactors, details reported in
the journal Scripta Materialia
Researchers have devised a quick way to test the structural materials used to build nuclear reactors, details reported in the journal Scripta Materialia
the University of Michigan, Ann Arbor, Los Alamos National Laboratory, Idaho
National Laboratory, Idaho Falls and TerraPower based in Bellevue, Washington,
have demonstrated the power of high-energy beams of charged particles (ions).
The ions can rapidly and consistently damage samples of ferritic-martensitic
steel, the material used in certain nuclear reactor components. The
significance of the result is that the breakdown closely replicates that seen
when high-energy neutrons from a nuclear reactor interact with the material -
damage accrues in a matter of days, rather than decades.
The structural components of advanced reactors such as the sodium fast reactor and the traveling wave nuclear reactor must be able to withstand the extreme levels of radioactivity from the fission reaction itself at temperatures well above 400 Celsius. Unfortunately, standard tests of such components are expensive, require increasingly rare test reactors and test periods that are impractical. Moreover, the samples themselves also become radioactive making subsequent studies and examination time consuming and expensive. Nevertheless, understanding how these structural components are affected by radiation at the microscopic level is critical to building long-lasting, robust and safe nuclear reactors.
To demonstrate the proof of principle with ion beams instead of conventional reaction irradiation, the team of researchers preloaded reactor components of ferritic-martensitic steel with atoms of helium gas, to simulate alpha particles. They irradiated the samples with an ion beam from a particle accelerator at 5 million electronvolts energy and a temperature of 460 degrees Celsius for several hours, and after which used transmission electron microscopy (TEM) to characterize the damage caused by the energetic ions penetrating the steel and observed microscopic holes (voids), dislocations and precipitates within the steel - none of which were present before ion irradiation.
Comparing this ion-beam damage with that seen in actual components of the same batch of steel used in a sodium fast reactor during the period 1985-1992, it was found that the types of defects (as well as their sizes and numbers) caused by neutron bombardment from the nuclear reaction to be closely reproduced by that with the ion beam experiments.
Lead author Gary Was hopes that their research will help develop "a stronger understanding of how to use ion irradiation to emulate neutron irradiation to enable the rapid development of new materials for advanced reactors as principal sources of clean energy". With additional work, a rapid, standardized experimental procedure may be developed for the routine evaluation of materials, facilitating the creation of more resilient components for nuclear reactors of the not-so-distant future.
Notes for editors
This article is "Emulation of reactor irradiation damage using ion beams" by G.S. Was, Z. Jiao, E. Getto, K. Sun, A.M. Monterrosa, S.A. Maloy, O. Anderoglu, B.H. Sencer and M. Hackett. It appears in Scripta Materialia, Volume 88, 1 October 2014, Pages 33–36 published by Elsevier. The article is available for free at www.materialstoday.com
Scripta Materialia is a letters journal of Acta Materialia, providing a forum for the rapid publication of short communications on the relationship between the structure and the properties of inorganic materials.
Materials Today is a community dedicated to the creation and sharing of materials science knowledge and experience. Supported by Elsevier, we publish high impact peer-reviewed journals, organize academic conferences, broadcast educational webinars and so much more.
Elsevier is a world-leading provider of information solutions that enhance the performance of science, health, and technology professionals, empowering them to make better decisions, deliver better care, and sometimes make groundbreaking discoveries that advance the boundaries of knowledge and human progress. Elsevier provides web-based, digital solutions — among them ScienceDirect, Scopus, Research Intelligence and ClinicalKey— and publishes over 2,500 journals, including The Lancet and Cell, and more than 35,000 book titles, including a number of iconic reference works. Elsevier is part of RELX Group, a world-leading provider of information and analytics for professional and business customers across industries. www.elsevier.com
+44 1865 843344