溶媒抽出による希土類元素分離

現代エレクトロニクスを支えるほぼ同一の元素の分離

Electronics & Semiconductors Global Industrial Scale $12 billion

概要

Rare earth elements (REEs) are separated from each other using multistage counter-current solvent extraction, exploiting the slight differences in their complexation with organophosphorus extractants. The 15 lanthanides plus yttrium and scandium have nearly identical chemical properties, making their separation one of the most challenging industrial processes. REEs are essential for permanent magnets (Nd, Pr, Dy), phosphors (Eu, Tb, Y), catalysts (La, Ce), and fiber optics (Er). China controls approximately 60% of REE mining and 85% of processing.

化学プロセス

REE-bearing ore (bastnaesite, monazite, or ion-adsorption clay) is dissolved in acid. The mixed REE solution is fed into a cascade of hundreds of mixer-settler units containing organophosphorus extractants (D2EHPA, PC88A, or Cyanex 572) in kerosene. Separation factors of 1.5-3.0 between adjacent lanthanides require 50-200 stages to achieve >99.9% purity for individual elements.

REE³⁺(aq) + 3HA(org) ⇌ REE(A)₃(org) + 3H⁺(aq) (extraction equilibrium, where HA = D2EHPA)
Separation based on slight differences in extraction constants across the lanthanide series

原材料

  • REE-bearing minerals (bastnaesite, monazite) — Mining (China, Australia, Myanmar) (REE source)
  • D2EHPA (di-2-ethylhexyl phosphoric acid) — Chemical synthesis (Selective extractant)
  • Hydrochloric acid (HCl) — Chlor-alkali process (Dissolution and stripping agent)

最終製品

  • Separated REE oxides (Nd₂O₃, Pr₆O₁₁, Dy₂O₃, etc.) — Permanent magnets, catalysts, phosphors, glass polishing (>99.9% individual REE purity)
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Environmental Impact

REE processing generates radioactive waste (thorium and uranium from monazite), acidic wastewater, and organic solvent emissions. Ion-adsorption clay processing in southern China has caused severe environmental damage including deforestation and waterway contamination. Tailings ponds from conventional mining are a long-term liability.

安全性の考慮事項

最新のイノベーション

Novel extractants with higher separation factors reduce the number of stages required.
Urban mining (recycling REEs from e-waste, magnets, and phosphors) is gaining momentum.
Ionic liquid extractants offer reduced VOC emissions compared to kerosene-based systems.

生産規模

350000

トン/年

$12 billion

市場価値

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Frequently Asked Questions

What industry uses 溶媒抽出による希土類元素分離?
溶媒抽出による希土類元素分離 is used in the electronics & semiconductors sector at global industrial scale scale.
What process is involved in 溶媒抽出による希土類元素分離?
REE-bearing ore (bastnaesite, monazite, or ion-adsorption clay) is dissolved in acid. The mixed REE solution is fed into a cascade of hundreds of mixer-settler units containing organophosphorus extractants (D2EHPA, PC88A, or Cyanex 572) in kerosene. Separation factors of 1.5-3.0 between adjacent lan
What is the economic significance of 溶媒抽出による希土類元素分離?
溶媒抽出による希土類元素分離 has a market value of $12 billion and annual production of 350,000 tons.
What is the environmental impact of 溶媒抽出による希土類元素分離?
REE processing generates radioactive waste (thorium and uranium from monazite), acidic wastewater, and organic solvent emissions. Ion-adsorption clay processing in southern China has caused severe environmental damage including deforestation and waterway contamination. Tailings ponds from convention
What raw materials are used in 溶媒抽出による希土類元素分離?
The main raw materials include: REE-bearing minerals (bastnaesite, monazite), D2EHPA (di-2-ethylhexyl phosphoric acid), Hydrochloric acid (HCl).