TY - JOUR
T1 - Erosion behavior of Ti-hBN multifunctional coatings in a custom-made planetary test rig at extreme lunar temperatures
AU - Sukumaran, Abhijith Kunneparambil
AU - Rengifo, Sara
AU - Aguiar, Brandon
AU - Mohammed, Sohail M.A.K.
AU - Scott, William
AU - Renfro, Michael
AU - Chu, Sang Hyon
AU - Park, Cheol
AU - Agarwal, Arvind
N1 - Publisher Copyright:
© 2024 Elsevier Ltd
PY - 2025/2
Y1 - 2025/2
N2 - Spacecraft landings and takeoffs on the lunar surface, along with extreme temperature variations between day and night (−196 to 150º C), cause high-velocity dust impacts and erosion, resulting in the premature failure of structures. Ti/2 vol% hBN coatings were deposited using atmospheric (APS) and vacuum plasma spray (VPS) using cryo-milled powder feedstock to protect the structural components. The erosion performance of coatings at extreme lunar temperature regimes (−150 to 150 °C) was evaluated in a custom-made planetary erosion test rig (PETR) at low (50 mph) and high impact velocities (250 mph). The mass loss of VPS coatings was reduced by 50 % compared to the APS coatings and 40 % compared to the Ti6Al4V substrate. The cryogenic temperature induces brittleness in the material, rendering it susceptible to extreme conditions of material loss. The particle impact-deformation behavior was captured using a high-speed camera to study the erosion mechanism. This analysis revealed chipping in substrates and brittle APS coatings, while particles rebounding and embedding were observed in VPS coatings. Energy calculations, aided by particle trajectory tracking from the high-speed camera, have conclusively shown that VPS coatings absorb 5–10 % more energy than APS coatings during erosion tests. A modified erosion index was developed incorporating the fracture toughness and temperatures. New erosion models for brittle and ductile target materials are proposed for developing erosion-resistant material systems.
AB - Spacecraft landings and takeoffs on the lunar surface, along with extreme temperature variations between day and night (−196 to 150º C), cause high-velocity dust impacts and erosion, resulting in the premature failure of structures. Ti/2 vol% hBN coatings were deposited using atmospheric (APS) and vacuum plasma spray (VPS) using cryo-milled powder feedstock to protect the structural components. The erosion performance of coatings at extreme lunar temperature regimes (−150 to 150 °C) was evaluated in a custom-made planetary erosion test rig (PETR) at low (50 mph) and high impact velocities (250 mph). The mass loss of VPS coatings was reduced by 50 % compared to the APS coatings and 40 % compared to the Ti6Al4V substrate. The cryogenic temperature induces brittleness in the material, rendering it susceptible to extreme conditions of material loss. The particle impact-deformation behavior was captured using a high-speed camera to study the erosion mechanism. This analysis revealed chipping in substrates and brittle APS coatings, while particles rebounding and embedding were observed in VPS coatings. Energy calculations, aided by particle trajectory tracking from the high-speed camera, have conclusively shown that VPS coatings absorb 5–10 % more energy than APS coatings during erosion tests. A modified erosion index was developed incorporating the fracture toughness and temperatures. New erosion models for brittle and ductile target materials are proposed for developing erosion-resistant material systems.
KW - Boron nitride
KW - Impact-deformation
KW - Lunar dust erosion
KW - Plasma spray coating
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U2 - 10.1016/j.triboint.2024.110339
DO - 10.1016/j.triboint.2024.110339
M3 - Article
AN - SCOPUS:85207792955
SN - 0301-679X
VL - 202
JO - Tribology International
JF - Tribology International
M1 - 110339
ER -