This work investigates the effect of a high-pressure Solution Treating and Aging (STA) heat treatment on the room-temperature (RT) and high-temperature (550 ◦C) tensile properties of the near-α Ti6242 alloy produced by PBF-LB. The treatment combines solutioning with Hot Isostatic Pressing (HIP) at 1000 bar, followed by argon quenching and aging. High-pressure heat-treatment parameters were first optimized by studying two α+β so lution temperatures (960 and 990 ◦C), corresponding to primary-α fractions of 25 % and 50 %. All samples were aged at 600 ◦C for 4 or 8 h to promote a bilamellar microstructure. The condition solutioned at 960 ◦C and aged for 8 h (HIP960_8) was selected for mechanical testing. In the second phase, HIP960_8 was compared with a standard STA treatment without HIP, using water quenching and identical thermal parameters (STA960_8), to evaluate the effect of cooling rate. Both were also compared with a β-solution STA treatment with pressurized nitrogen cooling (HT1040_8) designed to produce a fully lamellar structure. Atom Probe Tomography revealed Ti3Al precipitation in STA960_8, leading to higher YS and UTS than HIP960_8 at RT (+8 % on YS, +11 % on UTS) and 550 ◦C (+7 % on YS, +8 % on UTS). In contrast, HIP960_8 provided an excellent strength–ductility balance, with elongation increased by 40 % at RT and 22 % at 550 ◦C due to its reduced defect content. No STA condition formed silicides because of the low Si content, which contributed instead through solid-solution strengthening, particularly in HT1040_8. Tests at 550 ◦C confirmed that the bilamellar structure of HIP960_8 offers benefits comparable to solid-solution strengthening in HT1040_8.
Pirro, G., Belkacemi, L.T., Martucci, A., Altmann, M.L., Gaiba, F., Morri, A., et al. (2026). High-pressure solution treating and aging for additive manufactured near-alpha Ti6242 alloy: effects on microstructural properties and high-temperature tensile behaviour. MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 971, 150522-150534 [10.1016/j.msea.2026.150522].
High-pressure solution treating and aging for additive manufactured near-alpha Ti6242 alloy: effects on microstructural properties and high-temperature tensile behaviour
Pirro, Gianluca
Primo
;Gaiba, Filippo;Morri, Alessandro;Ceschini, LorellaUltimo
2026
Abstract
This work investigates the effect of a high-pressure Solution Treating and Aging (STA) heat treatment on the room-temperature (RT) and high-temperature (550 ◦C) tensile properties of the near-α Ti6242 alloy produced by PBF-LB. The treatment combines solutioning with Hot Isostatic Pressing (HIP) at 1000 bar, followed by argon quenching and aging. High-pressure heat-treatment parameters were first optimized by studying two α+β so lution temperatures (960 and 990 ◦C), corresponding to primary-α fractions of 25 % and 50 %. All samples were aged at 600 ◦C for 4 or 8 h to promote a bilamellar microstructure. The condition solutioned at 960 ◦C and aged for 8 h (HIP960_8) was selected for mechanical testing. In the second phase, HIP960_8 was compared with a standard STA treatment without HIP, using water quenching and identical thermal parameters (STA960_8), to evaluate the effect of cooling rate. Both were also compared with a β-solution STA treatment with pressurized nitrogen cooling (HT1040_8) designed to produce a fully lamellar structure. Atom Probe Tomography revealed Ti3Al precipitation in STA960_8, leading to higher YS and UTS than HIP960_8 at RT (+8 % on YS, +11 % on UTS) and 550 ◦C (+7 % on YS, +8 % on UTS). In contrast, HIP960_8 provided an excellent strength–ductility balance, with elongation increased by 40 % at RT and 22 % at 550 ◦C due to its reduced defect content. No STA condition formed silicides because of the low Si content, which contributed instead through solid-solution strengthening, particularly in HT1040_8. Tests at 550 ◦C confirmed that the bilamellar structure of HIP960_8 offers benefits comparable to solid-solution strengthening in HT1040_8.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.



