SMART ENERGY                                                                                        SMART ENERGY

          turn into amorphous phases over time. They looked   helping mitigate tritium retention, a major safety
          at how plasma conditions affect the buildup of silicon   concern.
          and carbon on surfaces, which can change how erosion
          behaves.                                             Additionally, because high-Z materials such as
                                                              tungsten emit intense radiation (X-rays) during
          EROSION RISKS: SiC AS A FUSION                      plasma disruptions, they can rapidly cool the
          SURFACE MATERIAL                                    plasma, destabilize confinement, and increase the

           Modeling with Wall Boundary Code (WBC) and Ion     risk of damage to other components. In contrast,
          Transport Monte Carlo with Dynamic (ITMC-DYN)       silicon’s lower radiation emission in SiC helps
          suggests that erosion risks for SiC in fusion reactors   preserve plasma stability and reduces the severity of
          may be overstated. While DIII-D (an advanced U.S.   disruption-induced energy loss.
          fusion research device in San Diego, designed to study
          plasma behavior under magnetic confinement) tokamak   While SiC isn’t yet a mainstream material in
          experiments using the Divertor Materials Evaluation   operational tokamaks, it’s on the radar as a
          System show high localized erosion, simulations for   plasma-facing material for future fusion reactor
          carbon-free DEMO reactors with full SiC coverage    designs. Integrated modeling using ITMC-DYN and
          predict a near-complete redeposition of silicon     WBC frameworks—validated by
          and carbon across the divertor. Redeposition is the   experiments—indicates that SiC surfaces, even
          process by which eroded atoms from plasma-facing    when amorphized under plasma conditions, retain
          components return to the surface instead of escaping   favorable erosion behavior due to high local
          into the plasma. This dramatically reduces net erosion   redeposition of sputtered particles. Compared
          and plasma contamination.                           with graphite, SiC offers better stability, reduced
                                                              contamination, and improved durability, especially in
 Tokamak schematic showing superconducting magnets in blue (Source: ITER)  Carbon erosion from SiC is estimated to be 7×   carbon-free tokamak environments.
          lower than from pure carbon (e.g., graphite) surfaces,


 fields—SiC stands out for its exceptional thermal   from high-melting-point materials such as tungsten
 stability and ability to withstand temperatures   (atomic number Z = 74, melting point 3,422°C). In ITER,
 exceeding 2,000°C.  these plates endure heat fluxes of 20 MW/m  (slow
 2
 transients).
 In addition to its heat resistance, SiC offers low
 neutron activation, which results in significantly less   DIVERTOR MATERIALS
 long-term radioactive waste than with conventional   Tungsten has long been used in divertors, but issues
 structural materials. It is also resilient to radiation   such as plasma contamination, disruptions, and high
 damage and mechanical stress. Furthermore, its   radiation during transients have led researchers to
 insulating properties make it valuable in magnets and   explore alternatives.
 current-drive systems.
 SiC stands out thanks to its excellent thermal
 Researchers are actively developing SiC-based   performance, resistance to melting via sublimation,
 composites, such as SiC/SiC, for integration into   and much lower radiation than high-Z materials
 critical reactor components, including blankets,   such as tungsten. Because silicon (Z = 14) radiates
 divertors, and load-bearing supports.  less intensely, plasma retains more energy, improves
 confinement, and operates more efficiently.
 Among these, the divertor plays a vital role.
 Positioned at the bottom of the vacuum chamber,   EROSION PHENOMENA
 it handles the heat and particles escaping from the   Scientists are concerned about how materials in
 plasma. Functionally, it extracts plasma byproducts,   fusion reactors erode, move, and affect the plasma’s
 shields reactor walls from thermal and neutron   core. One experiment showed that crystalline SiC
 damage, reduces plasma contamination, and   erodes twice as slowly as amorphous SiC, where atoms
 enhances overall plasma stability, especially in   are in a random, disordered arrangement.
 high-confinement operation.
 More studies confirmed this trend and explored how
 The divertor achieves this by shaping magnetic   erosion changes under different plasma temperatures.
 fields to guide escaping particles toward specially   Researchers also investigated how atoms are removed
 engineered divertor plates, where they can be safely   (sputtered), transported, and redeposited and how
 absorbed and cooled. Divertor plates are made   surfaces evolve—especially how crystalline SiC might

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