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SLB lithium production demo plant in Nevada reaches verified recovery rate of 96% lithium from brine

SLB announced that it has proven its solution for sustainable lithium production at scale at its demonstration plant in Clayton Valley, Nevada. The proprietary integrated solution combines SLB’s subsurface expertise with surface engineering of advanced technologies that include direct lithium extraction (DLE). It produces lithium 500 times faster than conventional methods while using only 10% of the land.

Operating at approximately one-tenth the size of a commercial-scale facility, the plant reached a verified recovery rate of 96% lithium from brine. The recovery rate was independently verified by WETLAB-Western Environmental Testing Laboratory of Nevada.

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SLB’s integrated solution is a complete, end-to-end process that includes advanced impurity treatment and concentration technologies to produce high-purity lithium carbonate or hydroxide. The solution also uses significantly less water, energy and fewer chemical reagents in comparison to other DLE-based offerings.

Lithium is a key enabler of electrification, so we must find ways to accelerate its production without adversely affecting the environment. SLB’s demonstration plant in Clayton Valley proves our unique integrated approach to produce scalable quantities of lithium in the fastest, most economical and sustainable way for today’s market. This accelerates deployment of viable commercial-scale facilities for high-quality lithium products that are the backbone of our electrification economy.

—Gavin Rennick, president of SLB’s New Energy business

The conventional alternative for producing lithium from brine at scale is evaporation. This process not only requires a significant amount of land but also results in massive water loss. Salt, underground minerals and used chemicals are then left at the surface, creating impact on biodiversity and the environment.

SLB’s lithium production solution enhances sustainability by reducing water use. The proprietary process also returns the spent brine, or the brine with a reduced lithium concentration, back to its source after the lithium is processed and separated.

The entire SLB solution, from extracting lithium from brine to converting it to technical-grade lithium carbonate, takes just hours. By comparison, evaporation methods can take up to 18 months and have a much lower recovery rate of 50% or less.

Lithium is sold commercially as lithium chloride, used as a feedstock for producing lithium metal; lithium carbonate, used in smartphones and short-range EVs; and lithium hydroxide, used in long-range EV batteries. SLB’s solution is highly flexible and can be adjusted to produce any of these products.

In proving this solution at its pilot plant, SLB completed specific technical milestones allowing it to fully qualify under the earn-in agreement with Pure Energy Minerals Ltd. and, at its option, may acquire 100% ownership interest in the Clayton Valley Project.

Comments

Albert E Short

This could make the Great Lithium Rush to the Salton Sea make the Gold Rush to Sutters Mill seem like light traffic.

JamesDo88039200

Lithium is a stepping stone to real third a nd fourth generation ion cells. Sodium ion is already here it's at least 1000 times more abundant than lithium . Potassium ion is right behind it. Calcium and magnesium are both 2+ vs 1+ for lithium or sodium that double their electrochemical potential per Mol. Aluminum is 3+ triple Li or Na and the U.S.military is already fielding aluminum graphene cells they blow lithium clean out of the water in every metric. Iron is 3+ or 4+ , titanium is 4+ no one has succeeded in using titanium as the primary ion species so it's 4+ is currently out of reach, Iron has been used at 2+ and 3+ though it's mass is an issue for mobile use. Titanium would be light enough for mobile uses its 4+ state would offer massive energy density if ever a anode/cathode combo could be found to use it's 4+ ion state. Regardless of the primary ion species recycling is going to be critical ad any geologist will tell you the mantra is "mine once, use many"

yoatmon

State it short and understandably, Li is crap. It was "Goodenough" for a start but lacks almost every potential for a durable future.

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