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使用YPO和YPO:20%Ce纳米颗粒对铕离子的吸附研究、光学性质以及与仪器中子活化分析相结合

Sorption Studies of Eu Ions Using YPO and YPO:20% Ce Nanoparticles, Optical Properties, and in Conjunction with Instrumental Neutron Activation Analysis.

作者信息

Perala Ramaswamy Sandeep, Putta Venkata Nagendra Kumar, Singh Bheeshma Pratap, Ningthoujam Raghumani Singh, Acharya Raghunath

机构信息

Department of Chemistry, GITAM University, Hyderabad 502329, India.

Chemistry Division, Bhabha Atomic Research Centre, Mumbai 400085, India.

出版信息

ACS Omega. 2025 Apr 8;10(15):14616-14625. doi: 10.1021/acsomega.4c06813. eCollection 2025 Apr 22.

DOI:10.1021/acsomega.4c06813
PMID:40290946
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12019472/
Abstract

The contamination of rare earth (RE) ions in an aqueous medium causes severe health hazards due to their toxicity. Hence, the removal of RE ions is necessary. In this work, we have used a concept of host-guest interaction which assists in the removal of RE ions by choosing the host as YPO nanomaterial and the Eu as foreign/guest ions. The YPO host having two different phases like tetragonal (pure YPO) as well as hexagonal structure (20 at. % Ce-doped YPO) are used for comparative studies. A sorption study of Eu was carried out with varying amounts of host (YPO and/or YPO:20% Ce) at different pH values, i.e., 3 (acidic), 7 (neutral), and 12 (basic). The loading capacity of the host was studied via instrumental neutron activation analysis (INAA) and photoluminescence (PL) experiments. Here, the role of quenching is clearly explained in the PL. INAA is very sensitive to europium owing to its higher absorption cross-section (σ ∼ 9.2 × 10 barn) and lower half-life (9.3 h). INAA using a short irradiation facility at PCF of the Dhruva reactor (1 min flux of neutrons at 5 × 10 n/cm/s) was effectively used to study the uptake of Eu using its activation product Eu (multi-γ-rays like 122, 344, and 842 keV). The order of uptake of Eu ions over nanoparticles is acidic < neutral < basic medium. In the acidic medium (pH = 3), emission peaks at ∼590 and ∼615 nm could not be observed due to low sorption of Eu over the host, whereas in the alkaline medium (pH = 12), their emission peaks are observed. It is interesting that at neutral pH, its uptake capacity is very good, and this has got a real case sample application for the removal of lanthanides.

摘要

由于其毒性,水介质中稀土(RE)离子的污染会导致严重的健康危害。因此,去除稀土离子是必要的。在这项工作中,我们采用了主客体相互作用的概念,通过选择YPO纳米材料作为主体,Eu作为外来/客体离子来协助去除稀土离子。具有四方相(纯YPO)和六方结构(20原子% Ce掺杂YPO)两种不同相的YPO主体用于对比研究。在不同pH值(即3(酸性)、7(中性)和12(碱性))下,用不同量的主体(YPO和/或YPO:20% Ce)对Eu进行了吸附研究。通过仪器中子活化分析(INAA)和光致发光(PL)实验研究了主体的负载能力。在此,PL中猝灭的作用得到了清晰的解释。由于Eu具有较高的吸收截面(σ ∼ 9.2 × 10靶恩)和较短的半衰期(9.3小时),INAA对铕非常敏感。利用Dhruva反应堆PCF的短辐照装置(中子通量为5 × 10中子/cm²/s,辐照1分钟)进行的INAA有效地用于研究Eu的活化产物Eu(122、344和842 keV等多γ射线)的摄取情况。Eu离子在纳米颗粒上的摄取顺序为酸性 < 中性 < 碱性介质。在酸性介质(pH = 3)中,由于Eu在主体上的吸附量低,在 ∼590和 ∼615 nm处未观察到发射峰,而在碱性介质(pH = 12)中观察到了它们的发射峰。有趣的是,在中性pH值下,其摄取能力非常好,并且在去除镧系元素方面有实际样品应用。

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