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PhD Thesis Defense: Aubrey Tang

Aug

08

Friday
11:00am - 12:00pm ET

Rm 232, Cummings Hall (Jackson Conf Rm)/Online

Optional ZOOM LINK
Meeting ID: 933 4224 2833
Passcode: 861471

"Wear of High-Entropy Alloys: Understanding effects of cryogenic temperatures and surface nitriding on wear behavior"

Abstract

Cryogenic tribological applications have become increasingly important with the development and innovation of advanced equipment in aerospace, polar regions, superconductivity, and more. Traditional lubrication methods are not viable under these harsh environments, so metallic materials must be able to maintain excellent mechanical properties and withstand the constant impact and wear alone. High entropy alloys (HEAs) have emerged as potential candidates for these applications because of their wide variety of excellent room temperature properties and proven ability of some HEAs to even improve their mechanical properties at extremely low temperatures. Despite their promising nature, very limited work has been done on understanding the wear behavior of these HEAs under cryogenic sliding conditions and even fewer work has focused on offering comparisons to other HEAs or traditionally-used materials.

This thesis investigates the tribological properties and specific wear mechanisms experienced by two single-phase face-centered cubic (f.c.c) HEAs, an equiatomic CoCrMnNiFe (Cantor HEA) and 1.1 at % C-doped Fe40.4Ni11.3Mn34.8Al7.5Cr6 (CHEA), as well as a two-phase HEA, Fe28.2Ni18.8Mn32.9Al14.1Cr6 (two-phase HEA), under cryogenic temperatures and room temperature. Overall, it was found that the two-phase HEA outperformed the 316 SS by up to 5x and the single-phase HEAs by up to 10x under the same sliding conditions at 77 K. It was observed that the better wear performance of the two-phase HEA was directly related to its sub-surface microstructural gradient and more even strain distribution. Amongst the single-phase HEAs, the CHEA showed the best wear resistance at cryogenic temperature due to the formation of stable and adherent oxides and the exclusive appearance of twins and secondary phases.

An additional chapter also explored the potential of utilizing a gas nitriding treatment to improve the wear resistance of the two-phase HEA. It was found that the nitrided pins only performed better than their as-cast counterparts under low sliding speed. This was due to the thickness, continuity, and chemistry of the mechanically mixed layer formed on each wear pin surface as well as changes in hardness.

Thesis Committee

  • Ian Baker (Chair)
  • Francis Kennedy
  • Rebecca Gallivan
  • Wen Chen (U Southern California)

Contact

For more information, contact Thayer Registrar at thayer.registrar@dartmouth.edu.