Extraction du Lithium des Saumures pour la Production de Batteries

Extraction du métal le plus léger des salars et des eaux géothermales

Energy & Battery Technology Global Industrial Scale $25 billion

Aperçu

Lithium is extracted from continental brines (salt flats in Chile, Argentina, Bolivia — the 'Lithium Triangle') by solar evaporation and chemical precipitation, or from hard-rock spodumene ore (Australia) by acid roasting. Lithium demand is surging due to lithium-ion batteries for EVs and energy storage. Brine extraction accounts for about 50% of global production and is lower cost, while spodumene processing is faster but more energy-intensive. Battery-grade lithium carbonate or lithium hydroxide requires >99.5% purity.

Procédé chimique

For brine: Lithium-bearing brine (200-2,000 ppm Li) is pumped to evaporation ponds where solar evaporation over 12-18 months concentrates lithium to 6,000+ ppm while NaCl and KCl crystallize out. Magnesium is removed by lime addition, and lithium carbonate is precipitated by adding soda ash (Na₂CO₃) at 90 degrees C. The precipitate is filtered, washed, and dried to battery-grade specification.

2LiCl(brine) + Na₂CO₃ →[90 degrees C] Li₂CO₃↓ + 2NaCl (lithium carbonate precipitation)
MgCl₂ + Ca(OH)₂ → Mg(OH)₂↓ + CaCl₂ (magnesium removal)
Li₂CO₃ + Ca(OH)₂ → 2LiOH + CaCO₃ (causticization to lithium hydroxide)

Matières premières

  • Lithium-bearing brine — Salt flats (Atacama, Hombre Muerto, Uyuni) (Lithium source (200-2,000 ppm Li))
  • Soda ash (Na₂CO₃) — Solvay process or trona mining (Lithium precipitation agent)
  • Calcium hydroxide (Ca(OH)₂) — Lime kiln (Magnesium removal agent)

Produits finis

  • Battery-grade lithium carbonate (Li₂CO₃) — NMC and LFP cathode production (>99.5% purity, <10 ppm Na, <5 ppm Fe)
  • Battery-grade lithium hydroxide (LiOH·H₂O) — High-nickel NMC cathode production (>56.5% LiOH, required for NMC 811)
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Environmental Impact

Brine evaporation consumes vast amounts of water in the world's driest regions, creating tension with local communities and ecosystems. Evaporation ponds cover hundreds of hectares. Spodumene processing requires energy-intensive acid roasting at 250 degrees C. Direct lithium extraction (DLE) technologies promise 90% less water use and land footprint.

Considérations de sécurité

Innovations récentes

Direct lithium extraction (DLE) using ion-exchange, adsorption, or membrane technologies can extract lithium from dilute brines in hours instead of months, with much lower water consumption.
Lithium extraction from geothermal brines provides both clean energy and lithium.
Recycling of end-of-life EV batteries is expected to provide 10-20% of lithium supply by 2035.

Échelle de production

130000

tonnes/an

$25 billion

valeur marchande

Plus dans Energy & Battery Technology

Frequently Asked Questions

What industry uses Extraction du Lithium des Saumures pour la Production de Batteries?
Extraction du Lithium des Saumures pour la Production de Batteries is used in the energy & battery technology sector at global industrial scale scale.
What process is involved in Extraction du Lithium des Saumures pour la Production de Batteries?
For brine: Lithium-bearing brine (200-2,000 ppm Li) is pumped to evaporation ponds where solar evaporation over 12-18 months concentrates lithium to 6,000+ ppm while NaCl and KCl crystallize out. Magnesium is removed by lime addition, and lithium carbonate is precipitated by adding soda ash (Na₂CO₃)
What is the economic significance of Extraction du Lithium des Saumures pour la Production de Batteries?
Extraction du Lithium des Saumures pour la Production de Batteries has a market value of $25 billion and annual production of 130,000 tons.
What is the environmental impact of Extraction du Lithium des Saumures pour la Production de Batteries?
Brine evaporation consumes vast amounts of water in the world's driest regions, creating tension with local communities and ecosystems. Evaporation ponds cover hundreds of hectares. Spodumene processing requires energy-intensive acid roasting at 250 degrees C. Direct lithium extraction (DLE) technol
What raw materials are used in Extraction du Lithium des Saumures pour la Production de Batteries?
The main raw materials include: Lithium-bearing brine, Soda ash (Na₂CO₃), Calcium hydroxide (Ca(OH)₂).