A Comparison Study on Formation and Stabilities of Chromium Bearing Spinels

Shuxuan Luo, Xingyue Ma, Ziwei Chen, Lei Zhang, Wanlin Wang, Yongqi Sun
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Abstract

Chromium, broadly present in metallurgical systems such as stainless steel slags and vanadium-bearing slags, tends to be in a trivalent form bound in spinel phases due to their ultrahigh stability. To explore the stability of chromium bearing spinels with different divalent cations, herein ACr2O4 (A=Mg, Zn, Mn) spinels were synthesized and stability-tested under both alkaline and acidic environments. X-ray diffraction (XRD) and refinement results reveal that MnCr2O4 exhibited the largest lattice parameters. X-ray photoelectron spectroscopy (XPS) results show that MnCr2O4 had the highest oxygen vacancy concentration, potentially triggering structural instability, consistent with the Fourier-transform infrared (FTIR) and Raman analyses. To further investigate the stability of ACr2O4 spinels in alkaline and acidic environments, we introduced CaO and SiO2, respectively, for high temperature calcinations. XRD analyses reveal that ACr2O4 spinels exhibited a high instability under an alkaline condition, with an increasing degree of instability for MgCr2O4, ZnCr2O4, and MnCr2O4 successively. We further quantified the relationship between the oxygen vacancy concentrations and the divalent cations containing in spinels as well as the spinel stabilities under an alkaline environment. Under an acidic condition, all ACr2O4 spinels demonstrated a relatively strong structural stability. The understanding of formation and stability of chromium bearing spinels under different conditions could contribute to potential modifications and applications of spinels especially with regard to resource recycling in metallurgy.

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含铬尖晶石的形成与稳定性对比研究
铬广泛存在于不锈钢渣和含钒渣等冶金体系中,由于其超高的稳定性,通常以三价形式结合在尖晶石相中。为了探索含有不同二价阳离子的铬尖晶石的稳定性,本文合成了 ACr2O4(A=镁、锌、锰)尖晶石,并在碱性和酸性环境下进行了稳定性测试。X 射线衍射(XRD)和细化结果表明,MnCr2O4 的晶格参数最大。X 射线光电子能谱(XPS)结果显示,MnCr2O4 的氧空位浓度最高,有可能引发结构不稳定,这与傅立叶变换红外(FTIR)和拉曼分析结果一致。为了进一步研究 ACr2O4 尖晶石在碱性和酸性环境中的稳定性,我们分别引入了 CaO 和 SiO2 进行高温煅烧。XRD 分析表明,ACr2O4 尖晶石在碱性条件下表现出较高的不稳定性,MgCr2O4、ZnCr2O4 和 MnCr2O4 的不稳定性程度依次增加。我们进一步量化了尖晶石中氧空位浓度与所含二价阳离子之间的关系,以及尖晶石在碱性环境下的稳定性。在酸性条件下,所有 ACr2O4 尖晶石都表现出较强的结构稳定性。了解含铬尖晶石在不同条件下的形成和稳定性有助于尖晶石的潜在改性和应用,特别是在冶金领域的资源回收方面。
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