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Lithium - All you need to know
Lithium is one of two commodities that has been constantly driving us
humans crazy alongside Cobalt, since the beginning of 2021 on strong demand
from the electric vehicles (EV) sector.
In 2020, the average price of a battery-grade lithium carbonate was an
estimated 8,000 U.S. dollars per metric ton and is expected to have a steady
growth.
In 2025, the price for 99% lithium carbonate is expected to be 7.56 U.S.
dollars per kilogram.
And the global lithium demand is expected to reach 4,450 metric tons of
lithium carbonate equivalent for non-rechargeable batteries by 2025.
In 2014, The Financialist stated that demand for lithium was
growing at more than 12% a year. According to Credit Suisse,
this rate exceeded projected availability by 25%.
Overall, the global lithium battery market is projected to grow
substantially in coming years, from 30 billion U.S. dollars in 2017 to over 100
billion U.S. dollars by 2025.
However global production has so far not fulfilled the global demand.
About Lithium:
- Soft and silvery-white
alkali metal.
- The lightest metal and
the lightest solid element.
- It is soft enough to be
cut with a knife.
- Has a very low density.
- Lithium is highly
reactive and flammable, therefore must be stored in mineral oil.
- It is never found free in
nature, exists in combined forms in ocean water or from brines(by
electrolysis of lithium chloride and potassium chloride).
- Lithium can float on even
the lightest hydrocarbon oils and is one of only three metals to
float on water(other two: sodium and potassium).
- Lithium is rarely found
in the Solar System than 25 of the first 32 chemical elements.
- It is a primordial
element produced in Big Bang nucleosynthesis.
How is Lithium found in Nature:
6Li and 7Li are the two stable natural isotopes of Lithium.
It is widely distributed on Earth though in combined forms with matter and
its content of seawater is very large.
It is estimated to be 230 billion tons of lithium in the oceans
but the concentration is 0.1-0.2ppm, making it more expensive to
extract with 2020 technology than from land based brine and rock.
Lithium constitutes about 0.002 percent of Earth’s crust. Found in minor part of igneous rocks and one of the largest concentrations in granites.
These sources are less expensive to mine than from rock such as spodumene,
petalite, and other lithium-bearing minerals.
The use of electrodialysis and electrochemical intercalation has been
proposed to extract lithium from seawater.
Extraction of Lithium:
Lithium was first discovered in the mineral petalite. Lepidolite and spodumene are
other common minerals which contain lithium.
Lithium extraction can be made from:
Primary resources such as ores/minerals (spodumene, petalite and
lepidolite) by acid, alkaline and chlorination processes and from brines by
adsorption, precipitation and ion exchange processes.
Secondary resources including the industrial processes like the recovery of lithium from
lithium ion batteries (LIBs).
According to the Handbook of Lithium and Natural Calcium, “Lithium
is a comparatively rare element, although it is found in many rocks and some
brines, but always in very low concentrations.
There are a fairly large number of both lithium mineral and brine deposits
but only comparatively few of them are of actual or potential commercial value.
Many are very small, others are too low in grade.”
Also occur minutely, in numerous plants, planktons and
invertebrates, at concentrations of 69 to 5,760 parts per billion (ppb)
with frequent evidences of Bioaccumulation in marine organisms.
Mineral springs and Geothermal wells too are great sources of Lithium, done by simple
filtration.
Recycling of Li-ion batteries:
To fulfil the penchant demand, we hope to recycle the end-of-life lithium-ion
batteries in the future to yield Lithium in order to reuse.
Unfortunately such technology is still in the developing phase. However a
few methods include the following:
Hydrometallurgy is the main method to recycle lithium cobalt oxide (LiCoO2) from
spent LIBs, leached with hydrogen peroxide (H2O2) and organic acid.
Cryogenisation– The cryogenic process consists of freezing still charged batteries with
liquid nitrogen (at −163°C) before being shredded to reduce the reactivity of
cells to zero.
Direct physical processing, LIBs are discharged and disassembled to the cell level.
Lithium reserves worldwide:
Although an accurate estimation of worldly lithium reserves is difficult
but US Geological Survey (USGS) estimated it to be 17 million
tonnes.
The surveyed reserves have continuously been updated since 2017 due to
rigorous exploration.
The top four lithium-producing countries of the world from 2019 are
Australia, Chile, China and Argentina.
Lithium Triangle:
The intersection of Chile, Bolivia, and Argentina make up the region known
as the Lithium Triangle.
The Lithium Triangle is known for its high quality salt flats including
Bolivia’s Salar de Uyuni, Chile’s Salar de Atacama, and Argentina’s Salar de
Arizaro.
The Lithium Triangle is believed to contain over 75% of existing known
lithium reserves.
Half the world’s known reserves are located in Bolivia along the central eastern
slope of the Andes range.
Exploration and prospection of Lithium at several other specific sites like
in Afghanistan, US etc is being carried out.
Lithium reserves in India:
Researchers at the Atomic Minerals Directorate( under India’s Atomic Energy
Commission) have estimated lithium reserves of 14,100 tonnes in a small patch
of land surveyed in the Southern Karnataka’s Mandya district recently. Also to
be India’s first ever Lithium deposit site found.
India currently imports all its lithium needs.
A “Khanij Bidesh India” has been setup to source and acquire mines in
Argentina, Bolivia and Chile.
The exploratory work is meanwhile also on to possibly extract lithium from
the brine pools of Rajasthan and Gujarat and the mica belts of Odisha and
Chhattisgarh.
Evolution of Lithium’s production and usage:
First application: In high-temperature lithium greases for
aircraft engines in the wake of World war 2.
Then came Lithium soaps.
Advanced applications:
Lithium-6 and lithium-7 produce tritium when irradiated by neutrons ie in nuclear
fusion weapons and inside hydrogen bombs in the form of lithium
deuteride.
Consequently during Cold war, US became the prime producer of lithium
between 1950s to 1980s. At the end, the stockpile of lithium was roughly 42,000
tonnes of lithium hydroxide and it got depleted by 75%.
With the surge of lithium demand in batteries in the 2000s, its demand
increased significantly and so does the number of new companies to get their
hands onto the Lithium business.
It’s expected future application is in the form of Geopolitical tool in
upcoming combating world running on renewable energy.
Chemical production of Lithium:
Lithium metal is produced through electrolysis from a mixture of
fused 55% lithium chloride and 45% potassium chloride at about 450 °C.
Applications of Lithium:
Lithium compounds are used in ceramics and glass, in primary
aluminium production, in the manufacture of lubricants and greases, rocket
propellants, vitamin A synthesis, silver solders, underwater buoyancy devices,
and increasingly in batteries.
One of lithium’s most well-known end uses is in lithium-ion batteries.
Lithium batteries are proving to be an effective and affordable alternative
to traditional batteries, and also in new battery applications. Lithium-ion
batteries are rechargeable and mostly used in portable electronics and electronic
vehicles.
In lithium-ion batteries, the lithium ions move from the negative electrode
to positive electrode and back while charging.
These batteries are highly flammable but are also low-maintenance. They
have a high energy density and a low self-discharge.
Some drawbacks include the fact that they are expensive to manufacture, and
that they require protection circuits to maintain the voltage safely.
It is to note that Electric vehicle mass production started in 2011–2012
and is expected to increase progressively between 3% and 10% from 2020 to 2025
and Lithium content in batteries varies from 0.60 g to 4.00 g in primary
batteries and from 0.35 g to 26.00 g in secondary batteries. We can therefore
anticipate what lies in the future.
Lithium-ion batteries are also the single-largest end user of lithium,
at 71 percent of global lithium consumption in 2020.
In 2017 the global demand for lithium in batteries was 87 kilotons of
lithium carbonate equivalent, this is expected to increase to 509 kilotons of lithium
carbonate equivalent in 2025.
The worldwide rechargeable battery market is dominated by lithium
ion batteries (51%) followed by NiMH (22%), NiCd (17%), and lithium
polymer (10%).
Lithium is mixed with other light metals such as aluminum and magnesium to form
strong, light-weight alloys (an alloy is a mixture of metals).
Some lithium, in the form of lithium carbonate or lithium citrate, is used
as medicine to treat gout (an inflammation of joints) and to treat serious
mental illness.
However there are several challenges associated
with its extraction and the subsequent impact on Environment.
To extract Lithium, miners drill holes in the salt flats and pump salty,
mineral-rich brine to the surface.
This process takes months and leads to water scarcity at places,
approximately 500,000 gallons per tonne of lithium.
Toxic chemicals can leak including Hydrochloric acid, in turn exacerbating
crisis.
Fires at where lithium-ion batteries recycling plants due to improper storage.
Global Investors are also looking to find an advancement in battery storage
technology that could complement lithium-ion batteries or find a way to make
them more efficient and less costly. “Breakthrough Energy Ventures” has been
funded by several billionaires including Bill Gates, Jeff Bezos and
Richard Branson, with the aim to find solutions for a zero-carbon
future through over $1 billion in investment.
Lithium has been considered as critical metal due to its high economic and
technological importance.
We know that Environmental healing remains fundamental to the introduction
of Electric vehicles and thereby Lithium batteries.
We shall strive to make their extractions still relevant to the cause ie. be ecologically sustainable.