Pashto Medium

A new scientific study highlights a breakthrough method affecting lithium production cost in battery manufacturing. Researchers at MIT and partner institutions introduced a low-temperature process that reduces energy use and waste. The study focuses on improving lithium production cost by changing how lithium is extracted from hard rock ore.

The research was published in Science and examines spodumene, a common lithium-bearing mineral. Conventional processing requires heating ore to nearly 1,000°C. It also uses sulfuric acid, which creates significant waste. These steps increase lithium production cost and raise environmental concerns.

The new method lowers lithium production cost by replacing high-temperature roasting with a chemical solution. Researchers use ammonium fluoride heated to about 70°C. This solution breaks down spodumene into separate streams of lithium, silicon, and aluminum. The approach improves efficiency and reduces overall processing energy.

In this system, lithium production cost decreases because lithium forms lithium fluoride in solution. This compound can be used directly in battery electrolytes. It can also be converted into lithium nitrate or lithium oxide for industrial applications. The simplified process reduces handling stages.

Silicon recovery also supports lower lithium production cost. The silicon converts into silicon dioxide after treatment with ammonia. It settles as a solid and can be reused in construction materials. This byproduct helps balance processing expenses.

Aluminum extraction remains the most energy-intensive stage. However, it occurs after separation, which improves system efficiency. The aluminum is heated in stages to produce high-purity aluminum oxide. This sequencing contributes to reduced lithium production cost compared to traditional methods.

The process also recycles key chemicals. Ammonia and hydrogen fluoride are reused to regenerate ammonium fluoride. This closed-loop system reduces material loss and supports lower lithium production cost over time. It also improves operational efficiency in continuous processing systems.

Economic analysis suggests strong potential savings. Conventional spodumene processing costs about $9,000 per tonne of lithium. The new method could reduce lithium production cost to just above $5,000 per tonne. This brings hard rock extraction closer to brine-based production costs.

Despite promising results, uncertainties remain. Final lithium production cost will depend on ore quality and infrastructure scale. Market fluctuations may also influence economic outcomes. However, the method provides a strong alternative approach for future lithium sourcing.

Researchers continue to test scalability for industrial adoption. The focus remains on reducing lithium production cost while maintaining material purity. This innovation may reshape how global lithium supply chains operate in the coming years.