FIVE NEW BATTERY TECHNOLOGIES THAT
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•Sep 27, 2020
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Batteries are everywhere in today’s
hyperconnected electrically propelled society. Sign up https://brilliant.org/ElectricFuture/
First 200 people get 20% off annual
premium subscription. Thanks to Brilliant for sponsoring this video! What if
your electric car could travel 1000 miles on a single charge, charge in 10
minutes, and last for 1 million miles? Today just about every electric car uses
lithium ion batteries. They’re pretty good, but ultimately are heavy and have
long charging times for the amount of energy they can store. According to Elon
Musk, battery modules are the main limiting factor in electric vehicle life. In
2019 he said the Tesla Model 3 drive unit is rated for 1 million miles, but the
battery isn’t as long lasting. To handle the predicted demand explosion for
electric vehicles over the coming decades, we’ll need to create a breakthrough
battery that is cheaper, longer lasting, more durable, and more efficient. We
must also address the issues of political and environmental sustainability to
ensure batteries remain tenable in an increasingly electric future. Over 80% of
world’s lithium deposits are found in China, and current technology also relies
heavily on cobalt, an element mostly found in the Democratic Republic of Congo.
After Tesla’s recent battery day, where Elon Musk announced a larger, tabless
4680 battery cell with improved energy density, greater ease of manufacturing,
and lower cost. The world’s attention is now more focused on batteries than
ever before, but Tesla isn’t the only show in town. Lithium air batteries.
Metal air batteries have been around for a while. You might find a little zinc
air button cell in a hearing aid, for example, but scaled up aluminum and
lithium air chemistries are also promising for the automotive and aerospace
industries. The potential for lightweight batteries with high energy storage
makes this battery technology promising. Lithium air batteries could have a
maximum theoretical specific energy of 3,460 W h/kg , almost 10 times more than
lithium ion. NASA researchers have also been investigating lithium air
batteries for use in aircraft. This technology still has a long way to go before
your take your next business trip is in an electric plane. Nanotech Batteries.
Nanotechnology has been a buzzword for several decades, but is now finding
applications in everything from nanoelectronics to biomedical engineering, and
body armor to extra-slippery clothing irons. Nanomaterials make use of
particles and structures 1-100 nanometers in size, essentially one size up from
the molecular scale. Carbon nanostructures also show great promise. Graphene is
one of the most exciting of these. Amprius go one stage further with their
anodes of ‘100% silicon nanowire’. The maker claims that they can achieve 500
Wh/kg which is in the range suitable for enabling electric aircraft in
partnership with Airbus. Nanomaterial research is promising Lithium sulphur batteries
are one emerging technology that can offer greatly improved energy densities
compared to lithium-ion. The theoretical maximum specific energy of this
chemistry is 2,567 Wh/kg compared to lithium ion’s 350 Wh/kg maximum. Solid
state electrolytes. A common theme in emerging technologies so far has been
researchers’ desire to develop solid state electrolytes. These would replace
flammable organic liquids with stable, crystalline or glassy-state solids, or
polymer-base. It is hoped that using these solid electrolytes would enable the
use of metallic lithium electrodes to provide higher output voltages and allow
for increased energy density. Panasonic have also been looking into solid state
electrolytes. It is notable that Tesla have been partnered with Panasonic in
their existing lithium-ion manufacturing capacity, but it is Toyota who have
publicly announced their collaboration with Panasonic to develop next
generation solid state batteries. Samsung too are working on solid state
batteries. Dual carbon batteries. Two carbon electrodes and a non-toxic
electrolyte with the ability to extract more power than from conventional
lithium ion, and their ability to charge 20 times faster, and these lithium-ion
variants could be the future for electric vehicles. Better batteries are also
important for the advancement of stationary storage from renewable energy
sources such as solar power. Tesla is also making headway into this sector,
with products like the powerwall home battery, and powerpack commercial energy
storage products. The technologies discussed in this video could have huge
implications on different battery powered transportation options besides just
electric cars. Imagine the potential in everything from electric bikes to
electric scooters and electric boats to electric airplanes. Consumer
electronics also stand to experience vast improvements in battery life in
devices such as smart phones, laptops, cameras, and more. The future is
electric!
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Future and
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