2026/01/05
Room-temperature laser crystallization of oxygen vacancy-engineered zirconia for additive manufacturing
Benavides-Guerrero, J.A.; Gerlein, L.F.; Angel-Ospina, A.C.; Fourmont, P.; Bhattacharya, A.; Zirakjou, A.; Vaussenot, F.; Ross, C.A.; Cloutier, S.G. (2025). Room-temperature laser crystallization of oxygen vacancy-engineered zirconia for additive manufacturing. Additive Manufacturing, vol. 111, 2025, 104969.
We demonstrate how strategically engineered oxygen vacancies enable room-temperature laser crystallization of zirconia (ZrO₂) in ambient air. Our sol-gel chelation synthesis creates amorphous ZrO₂ nanoparticles with a high concentration of oxygen vacancies that fundamentally alter the material’s energy landscape. These defects create sub-bandgap states that facilitate visible light absorption and dramatically reduce the energy barrier for crystallization. Under low-energy laser irradiation (405–532 nm), oxygen vacancies mediate a rapid phase transformation mechanism where atmospheric oxygen interacts with vacancy sites, triggering ionic rearrangement and crystallization without conventional high-temperature processing. For comparison purposes, this study also explores the thermal crystallization of black zirconia in an oxidative atmosphere, a process typically performed under vacuum or inert conditions. Through comprehensive characterization (FTIR, EPR, XPS, XRD, Raman), we establish that vacancy-mediated crystallization produces monoclinic ZrO₂ with preserved defect structures, yielding a distinctive black phase with 25.6 % oxygen vacancy concentration, significantly higher than thermally processed counterparts (9.2 %). This vacancy-enabled crystallization circumvents the need for extreme temperatures (>1170°C) typically required for ZrO₂ processing, making it compatible with additive manufacturing. Using a modified 3D printer with a 405 nm laser, we demonstrate patterned crystallization of complex architectures, opening new possibilities for fabricating advanced ZrO₂-based devices for photocatalysis, fuel cells, and energy applications. This work provides fundamental insights into defect-mediated phase transformations and establishes a new paradigm for room-temperature ceramic processing.