AI Article Synopsis
- Metal oxide thermal reduction using microwave-induced plasma was employed to create high entropy borides (HEBs), utilizing an argon-rich plasma for efficient energy transfer.
- Two synthesis methods were compared: boro/carbothermal reduction (with carbon) and borothermal reduction (without carbon), revealing distinct differences in microstructural and mechanical properties.
- The HEBs produced with carbon showed greater hardness (38 ± 4 GPa) and density, as well as reduced porosity, compared to those made without carbon (28 ± 3 GPa).
Article Abstract
Metal oxide thermal reduction, enabled by microwave-induced plasma, was used to synthesize high entropy borides (HEBs). This approach capitalized on the ability of a microwave (MW) plasma source to efficiently transfer thermal energy to drive chemical reactions in an argon-rich plasma. A predominantly single-phase hexagonal AlB2-type structural characteristic of HEBs was obtained by boro/carbothermal reduction as well as by borothermal reduction. We compare the microstructural, mechanical, and oxidation resistance properties using the two different thermal reduction approaches (i.e., with and without carbon as a reducing agent). The plasma-annealed HEB (Hf, Zr, Ti, Ta, Mo)B made via boro/carbothermal reduction resulted in a higher measured hardness (38 ± 4 GPa) compared to the same HEB made via borothermal reduction (28 ± 3 GPa). These hardness values were consistent with the theoretical value of ~33 GPa obtained by first-principles simulations using special quasi-random structures. Sample cross-sections were evaluated to examine the effects of the plasma on structural, compositional, and mechanical homogeneity throughout the HEB thickness. MW-plasma-produced HEBs synthesized with carbon exhibit a reduced porosity, higher density, and higher average hardness when compared to HEBs made without carbon.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10304851 | PMC |
| http://dx.doi.org/10.3390/ma16124475 | DOI Listing |
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