Detail publikačního výsledku

Atomic disorder and thermal stability in laser beam-shape-tailored 3D-Printed Zr-based bulk metallic glass under in-situ heating during high-energy X-ray diffraction

HADIBEIK, S.; GHASEMI-TABASI, H.; SCHRETTER, L.; GINGL, E.; COSTA, M.; BURN, A.; GAMMER, C.; GREER, A.; SPIECKERMANN, F.; ECKERT, J.

Originální název

Atomic disorder and thermal stability in laser beam-shape-tailored 3D-Printed Zr-based bulk metallic glass under in-situ heating during high-energy X-ray diffraction

Anglický název

Atomic disorder and thermal stability in laser beam-shape-tailored 3D-Printed Zr-based bulk metallic glass under in-situ heating during high-energy X-ray diffraction

Druh

Článek WoS

Originální abstrakt

This study demonstrates that tailoring the laser beam intensity profile in laser powder-bed fusion (LPBF) significantly influences the thermal and mechanical behavior of Zr-based bulk metallic glasses (BMGs). Compared to the conventional Gaussian beam (GB), printing with a shaped beam (SB) profile leads to a less relaxed glassy structure, as evidenced by higher reduced mean atomic volume V(T), increased thermal expansion coefficient (alpha th), and greater equivalent configurational entropy (Seq). These features indicate enhanced resistance to structural aging upon heating. Although both GB and SB samples exhibit fully amorphous microstructures under X-ray diffraction, transmission electron microscopy reveals the presence of nanocrystals embedded within the amorphous matrix. Upon in-situ heating, synchrotron XRD shows that SB-printed samples undergo slower structural relaxation, supported by shifts in the pair distribution function and total structure factor. Furthermore, fluctuation electron microscopy identifies increased atomic-scale heterogeneity and medium-range order in SB-processed material. Mechanically, dynamic analysis reveals that the SB sample exhibits lower damping capacity, as shown by a reduced tan delta (loss modulus/storage modulus), indicating superior stability under dynamic loading conditions. Together, these results suggest that beam shaping in LPBF offers a powerful approach to tune the performance of metallic glasses by controlling their atomic structure and relaxation dynamics.

Anglický abstrakt

This study demonstrates that tailoring the laser beam intensity profile in laser powder-bed fusion (LPBF) significantly influences the thermal and mechanical behavior of Zr-based bulk metallic glasses (BMGs). Compared to the conventional Gaussian beam (GB), printing with a shaped beam (SB) profile leads to a less relaxed glassy structure, as evidenced by higher reduced mean atomic volume V(T), increased thermal expansion coefficient (alpha th), and greater equivalent configurational entropy (Seq). These features indicate enhanced resistance to structural aging upon heating. Although both GB and SB samples exhibit fully amorphous microstructures under X-ray diffraction, transmission electron microscopy reveals the presence of nanocrystals embedded within the amorphous matrix. Upon in-situ heating, synchrotron XRD shows that SB-printed samples undergo slower structural relaxation, supported by shifts in the pair distribution function and total structure factor. Furthermore, fluctuation electron microscopy identifies increased atomic-scale heterogeneity and medium-range order in SB-processed material. Mechanically, dynamic analysis reveals that the SB sample exhibits lower damping capacity, as shown by a reduced tan delta (loss modulus/storage modulus), indicating superior stability under dynamic loading conditions. Together, these results suggest that beam shaping in LPBF offers a powerful approach to tune the performance of metallic glasses by controlling their atomic structure and relaxation dynamics.

Klíčová slova

Laser powder bed fusion, Bulk metallic glass, Shaped-beam technology, In-situ heating, Mechanical damping, Glassy state

Klíčová slova v angličtině

Laser powder bed fusion, Bulk metallic glass, Shaped-beam technology, In-situ heating, Mechanical damping, Glassy state

Autoři

HADIBEIK, S.; GHASEMI-TABASI, H.; SCHRETTER, L.; GINGL, E.; COSTA, M.; BURN, A.; GAMMER, C.; GREER, A.; SPIECKERMANN, F.; ECKERT, J.

Rok RIV

2026

Vydáno

01.12.2025

Periodikum

Materials Today Advances

Svazek

28

Číslo

September

Stát

Spojené království Velké Británie a Severního Irska

Strany od

100617-1

Strany do

100617-12

Strany počet

12

URL