Beryllium as the plasma-facing material in fusion energy systems—experiments, evaluation, and comparison with alternative materials

The history of plasma-facing materials in fusion systems is reviewed to explain the evolution of needs and requirements that has led to the interest in beryllium today. Critical fusion-related characteristics of beryllium, including outgassing properties, plasma-driven erosion, surface morphology mo...

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Bibliographic Details
Published in:Fusion engineering and design 1997-11, Vol.37 (4), p.481-513
Main Authors: Conn, Robert W, Doerner, Russell P, Won, Jongik
Format: Article
Language:English
Subjects:
Auger electron spectroscopy
Beryllium
Deuterium
Fusion reactions
Impurity
Morphology
Outgassing properties
Plasma-facing materials
X ray photoelectron spectroscopy
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Summary:The history of plasma-facing materials in fusion systems is reviewed to explain the evolution of needs and requirements that has led to the interest in beryllium today. Critical fusion-related characteristics of beryllium, including outgassing properties, plasma-driven erosion, surface morphology modification, and post-bombardment deuterium retention have been investigated under high-flux, steady-state deuterium plasma bombardment conditions. In experiments with beryllium, hydrogen and water molecules are observed to be the major desorbed species of as-received beryllium. Different beryllium samples manufactured using sintered powder metallurgical methods show similar outgassing behavior. However, cast beryllium samples desorb 20 times less gas than sintered beryllium. Simulating the divertor plasma conditions of the International Thermonuclear Experimental Reactor (ITER), the PISCES-B plasma generating facility is used to bombard targets with a deuterium plasma. The sputtering yield of beryllium is measured using a weight loss method. The target temperature and the partial pressure of residual gases during plasma bombardment are observed to be the critical parameters affecting erosion behavior. Data on sputtering yield for room temperatures (about 40°C) and high temperatures (above 250°C) samples is reported. It is also observed that at the higher temperatures, impurities from the plasma having low atomic number (such as carbon, nitrogen, and oxygen) are deposited on the beryllium surface. An impurity layer forms which is not eroded by extended plasma exposure. In-situ emission spectroscopy shows that the Be II line intensity drops by an order of magnitude as the deposited layer begins to form, and remains low during plasma exposure. This suggests that the impurity layer acts to shield the beryllium surface, thereby suppressing the erosion of beryllium. Estimates indicate that this film reduces the net erosion yield of beryllium by up to two orders of magnitude compared to a pure unprotected beryllium surface. On the other hand, no impurity deposition is observed when the beryllium target is maintained at room temperature (∼40°C) and the impurity concentration is kept at 1%. Depth-profiling together with auger electron spectroscopy (AES) and X-ray photoelectron spectroscopy (XPS) measurements demonstrate that the impurity layer is composed of beryllium oxide, amorphous carbon, and small amounts of beryllium carbide. Post-bombardment deuterium retention is
ISSN:0920-3796
1873-7196
DOI:10.1016/S0920-3796(97)00092-6