News & Analysis
/
Article

Cleaning a fusion reactor mirror with controlled plasma discharge

APR 15, 2022
Focused discharge can remove harmful metal atoms deposited on observation mirrors without interfering with reactor operations.
Cleaning a fusion reactor mirror with controlled plasma discharge internal name

Cleaning a fusion reactor mirror with controlled plasma discharge lead image

Observing a fusion reactor in progress is a tricky task due to the extreme environment. The detectors needed cannot be directly exposed to the reactor due to strong magnetic fields and particle bombardment, so instead a mirror is placed to give the diagnostics systems an indirect line-of-sight to the fusion plasma. However, eroded material from the reactor chamber walls will deposit onto the mirror surface, degrading the mirror’s optical properties over time.

Sackers et al. studied a possible solution to this problem, where a controlled plasma discharge is used to sputter away the deposited material and restore the mirror to working condition.

“In our study, we simulated coverage using a mirror mock-up made of tungsten to characterize in detail the conditions enabling a successful cleaning,” said author Marc Sackers. “The main requirements are limiting damage to the mirror, homogeneity of the processes, and cleaning speed. Our work illustrates operating scenarios of the discharge that fulfill these.”

The researchers employed a tungsten mirror to simulate the deposition of tungsten, the hardest material in the reactor chamber. They ignited argon plasmas in front of the mirror while varying plasma pressure and power coupled into the plasma to determine the optimal parameters to clean the mirror without damaging it.

Determining if the mirror’s optical properties are sufficiently restored is crucial, so the team is currently studying one such method that relies on backscattered hydrogen atoms from a local plasma.

“This approach makes it possible to provide an end of cleaning indicator,” said Sackers. “The admixture of hydrogen to argon changes the conditions in the plasma to an extent that has to be investigated in the future.”

Source: “Plasma parameters and tungsten sputter rates in a high-frequency CCP,” by M. Sackers, C. Busch, Ts. V. Tsankov, U. Czarnetzki, Ph. Mertens, and O. Marchuk, Physics of Plasmas (2022). The article can be accessed at https://doi.org/10.1063/5.0083613 .

Related Topics
More Science
/
Article
Experimental results confirm design principles for resonant-tunneling diode oscillators that could help make terahertz emitters commercially viable.
/
Article
Multifractal detrended fluctuation analysis confirms the Hamiltonian chaos of Saturn’s moon Hyperion, opening doors for validation of other chaotic systems in space.
AAS
/
Article
This month’s episode highlights the bright star Spica, now prominent high in the southwest after evening twilight. It’s leading the parade of constellations, along with the brilliant planet Venus, that will grace the Northern Hemisphere’s summer skies. You’ll also get to know other brights stars in Spica’s vicinity, along with excellent tips on how to be a better stargazer. So grab curiosity and come along on this month’s Sky Tour.
AAS
/
Article
The telescope should spot billions of astronomical objects in the next 10 years.