Journey to The Road, Part 2: LITHIUM

Journey to The Road, Part 2: LITHIUM

 

In our previous blog, we talked about the journey of oil, how it’s pulled from the earth, and how it ends up running automobiles all over the world. In this blog, we will look at the production of lithium and its journey to the end users on the road.

 

What is lithium, and why is it important to batteries?

Lithium is a chemical element with the symbol Li and atomic number 3. It is a soft, silvery-white alkali metal that is highly reactive and flammable. Lithium is one of the lightest metals and is used in various applications, including the production of ceramics, glass, and aluminum, as well as in the pharmaceutical industry.

Lithium is essential to batteries because of its unique chemical properties. Lithium-ion batteries are rechargeable and widely used in a range of devices, from mobile phones to electric cars. They work by using a lithium-ion to shuttle between the battery’s two electrodes, typically made of carbon and lithium cobalt oxide. The lithium ions move from the carbon electrode to the lithium cobalt oxide electrode when the battery is charged. The lithium ions move back to the carbon electrode when the battery is discharged. This movement of lithium ions creates the flow of electrons that produces the battery’s electrical current.

Lithium is an ideal material for batteries because it has a high energy density, meaning it can store a lot of energy in a small space. Lithium-ion batteries are also lightweight and have a long lifespan, making them well-suited for use in portable electronic devices and electric vehicles.

 

How is lithium extracted from the earth?

Lithium is primarily extracted from brine deposits and hard rock minerals. The extraction method used depends on the type of deposit.

Brine deposits are the most common source of lithium. These deposits are found in salt flats, or salars, which are large, flat areas of land where water has evaporated and left behind salt and other minerals. The brine in these deposits contains high concentrations of lithium, along with other minerals such as potassium and magnesium. To extract the lithium, the brine is pumped to the surface and concentrated in evaporation ponds, where the water evaporates, leaving behind the minerals. The remaining brine is then further concentrated, treated with chemicals to remove impurities, and processed into lithium carbonate or lithium hydroxide.

Hard rock minerals, such as spodumene, are another source of lithium. Spodumene is a type of mineral that contains high concentrations of lithium, and it is mined using conventional open-pit mining methods. The ore is then crushed and processed to remove impurities and concentrate the lithium. The resulting concentrate is then roasted at high temperatures to convert the lithium minerals to a form that can be leached with chemicals, producing lithium carbonate or lithium hydroxide.

Both brine and hard rock mining have their own advantages and disadvantages. Brine extraction is generally less expensive and less damaging to the environment, but the process can be slow and the purity of the lithium can vary. Hard rock mining, on the other hand, is faster and more reliable, but it can be more expensive and requires more energy to extract the lithium.

 

How does lithium get manufactured into a battery?

Manufacturing a lithium-ion battery involves several steps, including preparing the anode and cathode materials, assembling the cell, and adding the electrolyte.

  1. Preparing the anode and cathode materials: The anode and cathode materials are typically made of a variety of metals and chemicals, including lithium cobalt oxide, graphite, and other compounds. These materials are mixed with a binder and coated onto a thin copper or aluminum foil. The coated foils are then dried and cut into strips.
  2. Assembling the cell: The anode and cathode strips are alternated and separated by a layer of porous material, which serves as a separator. The entire assembly is then rolled up tightly and placed inside a cylindrical or prismatic cell casing. The casing is then filled with an electrolyte solution.
  3. Adding the electrolyte: The electrolyte is a lithium salt solution in an organic solvent, such as ethylene carbonate or dimethyl carbonate. The electrolyte is added to the cell through a small casing hole, which is then sealed.
  4. Formation: After the cell is assembled, it undergoes a process called formation. This involves applying a voltage to the cell, which drives the lithium ions from the cathode to the anode and back again. This process prepares the battery for its first use and can take several hours or days to complete.
  5. Final assembly: Once the battery is formed, it is typically packaged in a protective case, and the leads or terminals are attached to the anode and cathode foils. The finished battery is then tested to ensure it meets the required capacity, voltage, and energy density specifications.

Overall, the manufacturing of a lithium-ion battery is a complex process that requires careful attention to detail to ensure that the finished product is reliable and safe for use.

 

How do lithium batteries get to the end consumer?

Lithium batteries are manufactured by specialized companies and then distributed through a complex network of suppliers, manufacturers, and retailers before they reach the end consumer. Here is an overview of the process:

  1. Production: Lithium batteries are produced by specialized manufacturers with expertise in creating the battery chemistry, design, and performance. The manufacturers produce large volumes of batteries, which are then sold to distributors and retailers.
  2. Distribution: Once the lithium batteries are produced, they are typically distributed through a network of suppliers, manufacturers, and retailers. The distributors may sell the batteries directly to manufacturers, who incorporate them into their products, such as smartphones, laptops, or electric vehicles. Alternatively, the distributors may sell the batteries to retailers, who then sell the batteries directly to the end consumer.
  3. Retail: Retailers that sell lithium batteries include electronics stores, hardware stores, online retailers, and specialty battery stores. These retailers typically stock a range of battery sizes and chemistries to meet the needs of different customers.
  4. Transportation: Lithium batteries are classified as hazardous materials and are subject to strict transportation regulations. When batteries are transported, they must be packaged and labeled according to the regulations, and carriers must comply with special handling and safety procedures.
  5. Disposal and recycling: At the end of their useful life, lithium batteries can be disposed of at authorized recycling centers or collection points. Recycling lithium batteries is important to prevent environmental contamination and to recover valuable metals that can be reused in new battery production.

Overall, the distribution of lithium batteries is a complex process that involves specialized manufacturers, distributors, and retailers, as well as strict regulations for transportation and disposal. The goal is to ensure that lithium batteries are safely and efficiently delivered to the end consumer.

 

How do lithium batteries benefit electric vehicles?

Lithium-ion batteries are the most common type of battery used in electric vehicles (EVs), and they provide several benefits for these vehicles, including:

  1. High energy density: Lithium-ion batteries have a high energy density, which means they can store a lot of energy in a relatively small and lightweight package. This is important for electric vehicles, as it allows them to have a more extended driving range while keeping the battery pack size and weight manageable.
  2. Fast charging: Lithium-ion batteries can be charged more quickly than other types of batteries, allowing electric vehicles to be recharged more quickly. Fast charging is becoming increasingly crucial as EV infrastructure improves, allowing drivers to spend less and more time on the road.
  3. Long lifespan: Lithium-ion batteries have a long lifespan and can last many years with proper maintenance. This is important for electric vehicles, which are a significant investment for most consumers. A long-lasting battery pack ensures that the car will continue to provide reliable service for many years.
  4. Low maintenance: Lithium-ion batteries require very little maintenance compared to other types of batteries. They do not need to be topped up with water and do not require regular equalization or other maintenance procedures.
  5. Environmental benefits: Electric vehicles powered by lithium-ion batteries produce no tailpipe emissions, which means they do not contribute to air pollution. They also have lower lifecycle emissions than gasoline-powered vehicles, even when considering the emissions associated with battery production.

Overall, the high energy density, fast charging, long lifespan, low maintenance, and environmental benefits of lithium-ion batteries make them an ideal choice for electric vehicles. As battery technology continues to improve, electric vehicles will likely become even more attractive to consumers, helping to reduce reliance on fossil fuels and promote a cleaner, more sustainable transportation system.

 

Make The Switch.

The Switch Lab™ is an engaging hands-on project that your students will love. It makes learning complex topics fun and exciting. This new EV technology isn’t ahead of its time. It’s right on time.

Our reusable EV Kit is ideal for students interested in renewable energy, advanced technology, or automobile design. The Switch Lab teaches students how to work with their hands, solve problems, collaborate as a team, learn about systems, and gain experience in cutting-edge automotive technology. Contact us today to learn more about how Switch Vehicles can benefit your school. Let’s grow the EV tech future together!