Highlights
- Nanjing University researchers develop a groundbreaking method to distinguish all 17 rare earth elements using a dual-ligand nanopore sensing strategy.
- The innovative approach offers 99.6% accuracy in elemental identification at the single-molecule level.
- Potential for compact and cost-effective field deployment
- Technology represents a significant advancement in rare earth element detection
- Potentially enhances China’s scientific leadership in resource exploration and analysis
In a scientific milestone with global implications, Professor Huang Shuo’s (opens in a new tab) research team at Nanjing University (opens in a new tab) has developed a groundbreaking method (opens in a new tab) to rapidly and accurately distinguish all 17 rare earth elements (REEs)—a feat long considered technically prohibitive due to their nearly identical electronic configurations.
This breakthrough leverages a dual-ligand nanopore sensing strategy, achieving unprecedented 99.6% accuracy in differentiating individual REEs at the single-molecule level, and has been successfully validated on realmineral samples, such as bastnäsite.
Superior Detection Models
Traditional REE detection methods—such as ICP-MS, XRF, and NAA—suffer from tradeoffs between sensitivity, complexity, cost, and field applicability. The new approach employs the MspA protein nanopore from Mycobacterium smegmatis, customized with fixed and free ligands (NTA and ANTA) that chelate rare earth ions with distinct coordination signatures. These signals are then decoded via machine learning. In addition to enabling precise identification, the platform also observes the lanthanide contraction effect in real time—offering new insights for elemental science.
Unlike bulky and expensive instrumentation, the Nanjing method promises compact, cost-effective deployment suitable for field use, opening a new frontier for real-time REE exploration and analysis. Critically, this technique overcomes the historical bottleneck of REE co-detection in complex ores, offering a powerful alternative to current lab-dependent assays and enabling on-site identification of strategic resources.
Implications for the West
This innovation could very well enhance China’s scientific leadership in the rare earth value chain, not just in mining and refining, but also in elemental identification and ore characterization. Western nations reliant on Chinese REEs must note: China is not only tightening political control over rare earth supply but now leapfrogging in foundational technologies that enable more efficient resource mapping and extraction, as Rare EarthExchanges chronicles on a nearly daily basis. A U.S. or allied technological counter-response is urgently needed to catch up and maintain competitiveness in critical mineral independence, a process that will likely take a decade or more.
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