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Journal of Synthetic Crystals ›› 2026, Vol. 55 ›› Issue (6): 930-939.DOI: 10.16553/j.cnki.issn1000-985x.2026.0013

• Research Articles • Previous Articles     Next Articles

Effect of Oxalic Acid Pretreatment on Low-Temperature Densification and Optical Properties of Y2O3 Transparent Ceramics

LIN Haining1,2(), CHEN Jian1, HUANG Jiquan1, LIU Xin1,2, GUO Wang1,2()   

  1. 1.State Key Laboratory of Functional Crystals and Devices,Fujian Institute of Research on the Structure of Matter,Chinese Academy of Sciences,Fuzhou 350002,China
    2.College of Chemistry and Materials Science,Fujian Normal University,Fuzhou 350007,China
  • Received:2026-01-27 Online:2026-06-20 Published:2026-07-07
  • Contact: GUO Wang

Abstract: Yttrium oxide (Y2O3) transparent ceramics have been widely studied for infrared windows,corrosion-resistant components,solid-state lasers,and scintillator hosts because of their broad optical transparency range,excellent chemical stability,and low thermal expansion coefficient. However,their widespread application is hindered by the high melting point of Y2O3,which necessitates energy-intensive sintering processes at temperatures often exceeding 1 800 ℃ to achieve full densification. Conventional approaches to lower the sintering temperature typically rely on either complex,time-consuming synthesis of ultra-high-purity,nano-sized powders or on expensive advanced sintering techniques like hot isostatic pressing (HIP) or spark plasma sintering (SPS),limiting their scalability and cost-effectiveness. In this study,we report a simple,scalable,and low-cost strategy to dramatically enhance the sinterability of commercial Y2O3 powder through an oxalic acid liquid-phase pretreatment,enabling its low-temperature densification via vacuum pressureless sintering,which is a method that is both industrially favored and economically viable.The method involves treating ball-milled commercial Y2O3 powder with a 1.2 mol/L oxalic acid solution,followed by filtration,washing,and a final calcination at 700 ℃. This treatment is shown to have a profound,multi-faceted activation effect. It not only efficiently removes surface-adsorbed impurities and carbonates,as confirmed by FT-IR analysis,but also refines the average particle size from 1.0~1.3 μm to approximately 300 nm. Crucially,the chelation between Y3+ and C2O42- leads to the in-situ formation of a yttrium oxalate precursor,which upon decomposition generates a substantial population of 30~50 nm Y2O3 nanoparticles. These nanoscale particles act as highly reactive sintering seeds,significantly boosting the overall sintering activity of the powder.The impact of this pretreatment on the sintering behavior and optical quality of Y2O3 ceramics was systematically investigated. For 2.0%(atomic fraction) ZrO2-doped Y2O3,the oxalic acid treatment reduced the densification temperature by approximately 100 ℃. Near-full densification with a uniform,fine-grained microstructure was achieved at just 1 700 ℃ for 5 h under vacuum,a temperature at which untreated samples remained porous and opaque. This low-temperature densification is attributed to the combined effects of improved powder dispersion,and the presence of the nano-sized Y2O3 particles that enhance grain boundary diffusion. The superior sintering activity and microstructural uniformity directly translated into outstanding optical performance. Sintered at 1 750 ℃,the treated Y2O3 ceramics exhibit a maximum in-line transmittance of 75.8% at 600 nm,representing a significant advancement over untreated samples which showed no transmittance at this wavelength under identical conditions.In conclusion,this work introduces a highly effective powder activation strategy that bridges the gap between low-cost commercial precursors and the demanding requirements of high-performance transparent ceramics. By demonstrating that a simple oxalic acid wash can match the sintering efficacy of complex powder synthesis routes,this research provides a new paradigm for the low-temperature,cost-effective fabrication of high-melting-point oxide ceramics.

Key words: Y2O3 transparent ceramics; oxalic acid pretreatment; vacuum pressureless sintering; optical transmittance; microstructure; densification behavior

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