We've updated our Privacy Policy to make it clearer how we use your personal data. We use cookies to provide you with a better experience. You can read our Cookie Policy here.
Alexander Beadle is a science writer and editor for Technology Networks. Before this, he worked as a freelance science writer, writing features and reporting on breaking news in materials science, environmental science and drug research. Alexander holds an MChem in Materials Chemistry from the University of St Andrews, Scotland.
Batteries have become an essential part of daily life – from household appliances to cell phones and other gadgets. As our scientific understanding of battery chemistry has improved, so too has the quality of the batteries that the industry is able to produce.
As illustrated by the rise of electric vehicles (EVs), the evolution of new batteries with improved energy storage capabilities and other metrics can give rise to new technologies and even entire sectors that have the potential to revolutionize modern life.
Download this infographic to explore:
The foundational principles of battery science
The current state of investment in battery research projects
The key innovation that look set to propel the sector to new heights
Major investments in
batteries research
Batteries have become an essential part of daily life – from household appliances to cell
phones and other gadgets. As our scientific understanding of battery chemistry has
improved, so too has the quality of the batteries that the industry is able to produce.
As illustrated by the rise of electric vehicles (EVs), the evolution of new batteries with
improved energy storage capabilities and other metrics can give rise to new technologies
and even entire sectors that have the potential to revolutionize modern life.
In this infographic, we explore the foundational principles of battery science, the
current state of investment in battery research projects and the key innovations
that look set to propel the sector to new highs over the coming years.
tment & Innovation Investment & Innovation Investment & Innovation Investment & Innovation Invest & Innovation Investment & Innovation Investment & Innovation • Investment & Innovation Investment &Batteries, explained
There are many different types of battery currently in development, but the most
popular type of rechargable battery that we use today is the lithium–ion battery.
The classical lithium–ion battery consists of a single or multiple lithium–ion cells
connected in series. The key components of a lithium–ion cell are:
The bridge between
a battery or a cell and
the external circuit,
ordinarily an aluminum
copper foil.
The Department of Energy has pledged
$42 million to fund 12 research
projects developing improved battery
materials and new battery chemistries
for use in EVs.
In 2022, the UK announced an
additional £211 million of government
funds to be distributed to battery
research projects via the Faraday
Battery Challenge, bringing the total
amount of government investment in
battery research to £541 million.
This is the negative
electrode of the cell, which
stores and releases lithium
ions during charging and
discharge. Graphitebased anodes are used in
the majority of commercial
batteries, due to its low
cost, low toxicity and high
abundance.
A permeable membrane
placed between the
electrodes to prevent
short circuits while
allowing the flow of
lithium ions through
the cell.
This is the positive
electrode of the cell and
the source of the battery’s
lithium ions. Cathode
materials are usually some
form of metal oxide that
can act as a sink for the
lithium ions.
An electrically conductive
layer, often an inorganic
lithium salt in organic
solution, that allows the
ions to pass between the
anode and cathode.
Current collectors
United States United Kingdom
Electrolyte
Anode Separator
Lithium
ions
Cathode
The European
Commission has approved
a pan-European project
by seven member states –
Belgium, Finland, France,
Germany, Italy, Poland
and Sweden – to provide
€3.2 billion in funding
to support research and
innovation in battery
science.
The Ministry of Trade,
Industry and Energy
announced a combined
₩7 trillion funding
package for the battery
industry, including ₩50
billion in research grants
for manufacturers of
lithium, phosphate and
lithium iron phosphate
(LFP) batteries.
The Ministry of Economy,
Trade and Industry has
established a Green
Innovation Fund, which
includes a budget of
up to ¥151 billion for a
project investigating highperformance battery
materials and battery
recycling technologies.
European Union South Korea Japan
Innovation in
battery research
While there is much still to explore in battery science, there are a number of recurring
themes that appear regularly when examining the investments and grants being made
in battery research.
Lithium–ion batteries are the most common commercial battery type today, but there are a
whole range of other possible battery chemistries out there that show good potential.
Investment in this area is targeted at breaking down the barriers to commercialization for
alternatives to lithium–ion batteries, such as ensuring good operation at low temperatures
and the creation of suitable electrolytes.
Among materials scientists, one very active area of research is the development of new and
improved battery materials for lithium–ion batteries.
The capacity and performance of a battery can be greatly affected by the quality and
chemistry of its constituent parts. Novel anode materials, including alloys, silicon-based
compounds, carbon-based compounds and transition metals are all under investigation. Due
to the increasing costs and unsustainable mining practices associated with some elements
used in traditional cathode materials, there is also significant investment being made to
support the development of novel cathode materials that reduce the need for such elements.
According to a new report authored by the International Energy Agency, approximately 14% of
all new cars sold in 2022 were electric. This is up from 9% in 2021 and less than 5% in 2020.
With the EV sector expected to continue this strong growth trend through the coming years,
there is a significant focus on investment in battery manufacturing in order for the sector to
continue to meet consumer demand. Equally, there is strong investment in battery research
projects that specifically target the development of improved batteries for use in EVs.
Alternative battery chemistries
Improved battery materials
The future of electric vehicles
Project K (California, USA)
Awarded $2.6 million to develop
and commercialize a potassium–ion
battery. Project award comes via the
US Department of Energy’s Electric
Vehicles for American Low-Carbon
Living (EVs4ALL) program.
NEXGENNA (United Kingdom)
Project received £15.9 million in project
funding to develop the next generation
of sodium–ion batteries. The funding
comes via the Faraday Institution.
The University of Maryland
(Maryland, USA)
Awarded $4.8 million to increase
the charge/discharge-rate capability,
energy density and operating
temperature window of solid-state
lithium metal batteries. Awarded via
the EVs4ALL program.
FutureCat (United Kingdom)
Project received £14.4 million in project funding
to develop high nickel content, high performance
cathode materials for lithium–ion batteries. The
funding comes via the Faraday Institution.
Next-Generation Storage Battery and Motor
Development (Japan)
Project given a budget of up to ¥151 billion to deliver
improved storage batteries. This includes the development
of new materials technology that will reduce the use of
high-dependency materials such as cobalt and graphite.
An unnamed Important Project of Common
European Interest (IPCEI) (European Union)
Will receive approximately €3.2 billion from seven EU member
states. The project plan includes the enhancement of existing
battery materials and the development of new ones as one of its
four key areas of focus.
SOLBAT (United Kingdom)
Project awarded £21.8
million in funding to
demonstrate the feasibility
of a solid-state battery
with superior performance
to lithium–ion in EV
applications. Project funding
comes via the Faraday
Institution.
24M Technologies
(Massachusetts, USA)
Awarded $3.2 million to
develop low-cost and fastcharging sodium metal
batteries with good lowtemperature performance
for EVs. Awarded via the
EVs4ALL program.
Solid Power Operating
(Colorado, USA)
Awarded $5.6 million to
develop a 3D-structured
lithium metal anode and
novel sulfur composite
cathode to enable highenergy and fast-charging
EV battery cells. Awarded
via the EVs4ALL program.
Sponsored by
Download the Infographic for FREE Now!
Information you provide will be shared with the sponsors for this content. Technology Networks or its sponsors may contact you to offer you content or products based on your interest in this topic. You may opt-out at any time.