Rare Earth Elements (REE) separation is the third and the final step in making REE compounds from mineral ore. REE invariably occur together in nature and therefore any given REE mineral will contain several or most of the 17 REE in variable quantities. Consequently, when a rare earth concentrate (REC) is produced, a mixture of REE is present that needs to be further refined into their individual elements, whether in their oxide or metal form, before they can be applied in their various end products.

To get to a REC, the first step is beneficiation where the natural REE-bearing minerals disseminated through the ore are liberated by crushing and grinding followed by concentration through flotation, magnetism and other means based on their physical properties. The second step is hydrometallurgy, a processing method in which the mineral concentrate resulting from the beneficiation is broken down, using thermal and chemical agents. Although hydrometallurgy varies from project to project, depending on the REE mineral in question, both steps are relatively simple and quite achievable through conventional methods. Nevertheless, it comes down to cost, scale, environmental regulations, infrastructure and permitting when choosing the optimal combination of beneficiation and hydrometallurgy for any project.

Both these steps have only a limited capability to differentiate between the individual REE and are often done at the expense of significant overall recoveries.The reason being is that the chemical properties of REE do not deviate significantly from one another. Consequently, purification and separation of individual REE today is tremendously tedious and requires several processes with the majority of the world’s REE processing facilities today located in China. A REE refinery often includes many consecutive steps, each resulting in minute improvement in the complex REE stream with the overall processing cycle taking a great deal of time.


Today, countercurrent solvent extraction is generally accepted as the most appropriate commercial technology for separating rare earths. The key step in the extraction process is the selection of a suitable solvent combined with a suitable extraction condition. Effective extraction and separation is unlikely to be achieved in a single step, and it is therefore necessary to prepare an aqueous solution containing the REE and extract this solution repeatedly with an organic solvent. This makes the acid and the base the main consumables in the solvent extraction process, and the spent REE acidic solution becomes one of the main pollution sources. Using this method, a plant producing multiple single rare earth products may contain hundreds of stages of mixers and settlers. As a result, many separation stages are typically needed to obtain a pure product.Inherent aspects of the solvent extraction technique:

  • Large amount of organic and inorganic solvents in the process flow sheet
  • Chemical adjustment based on REE distribution of concentrate
  • High capital cost chemical facilities
rare earth solvent extraction proces

Figure 1: Example costs of solvent extraction plants

(SX Plant)
Separation Plant CAPEX (M$)Capacity
(REO tpy)
CurrencyStatusSeparation Capability
LynasMount WeldMalasian/a122,000AUDBuiltLa, Ce, Nd/Pr, M&HREE con
MolycorpMountain PassUSAn/a240,000USDBuiltLa, Ce, Nd/Pr, M&HREE con
FrontierZandkopsdriftSouth Africa49820,000USDPEA 2012All REO, Ho+Er+Tm+Yb con
AvalonNechalachoUSA42310,000CADFS 2013All REO, Ho+Er+Tm+Yb con
ArafuraNolan’s BoreUSA12920,000AUDPFS 2012La, Ce, Pr-Nd, M&HREE con
PeakNguallaTanzania4910,000USDPFS 2014La, Ce, Pr-Nd, M&HREE con
QuestStrange LakeCanada19010,000CADPEA 2014All REO

1Built & Operational (only phase 1 for 11,000 tpy was commisioned). SX cost estiamted at $200M-$400M$
2Modernization and expansion of existing mine and infrastructure. Designed for 40K, current Production target approx 19K tpy. SX cost estimated at $400-$800M

Scientific reading on solvent extraction:

Rare Earths in the media: