By 2025, game-changing solid-state batteries may disrupt lithium-ion batteries
Energy, like art, is life. The 1987 movie Batteries Not Included follows tenants who enlist alien robots to save their building. In the sci-fi film, aliens settle in the building's shed, forming a bond with the tenants.
Fast forward to 2024: A real-life, power-saving battery that lasts longer, charges faster, and cuts the risk of fire—sounds too good to be true, right?
Solid-state batteries are poised to deliver exactly that. With cutting-edge designs swapping liquid electrolytes for solid ones, they promise to redefine how we power electric vehicles, smartphones, air taxis, and more.
It doesn’t stop there.
While industry giants like CATL, BYD and QuantumScape are racing to commercialise this technology, questions loom: Can they overcome the high production costs?
Will they scale in time? Experts suggest that by 2025, the game-changing potential of solid-state batteries may finally hit the market.
The world is watching. Could this be the power source of tomorrow, or will its rollout face insurmountable hurdles?
Enter solid-state batteries
While we're quite not there yet, the shift to SSBs, that is, replacing Li-ion's liquid electrolyte with a solid material, offers a number of advantages:
- Increased energy density: Solid-state batteries can store more energy in a smaller package, enabling longer driving ranges for electric vehicles.
- Enhanced safety: Solid electrolytes are less flammable and more stable than liquid electrolytes, reducing the risk of fires and explosions.
- Faster charging: These batteries can charge much faster than traditional lithium-ion batteries.
The science behind the scenes
A number of economic and technical factors are at play: battery costs have gone down dramatically. In the last 15 years, given the speed of developments in the battery space, a staggering 90 per cent drop in the cost of battery packs has already occurred, bringing a real-life benefits for planet Earth, according to the US Department of Energy (DOE).
There's a fierce race underway in the labs and factories. Industry giants and top universities are pouring millions into supercharging battery technology. The trend, given the huge potential payoffs, seems unstoppable.
SSBs represent a radical leap in battery technology promises longer range, faster charging, and a cleaner energy future.
With a dramatic leap in energy density, at least double the juice from today's best lithium-ion batteries, the rise of SSBs could power the future, where cars drive longer and charge faster.
• SSB also allows for faster charging — potentially from 0 to 80 per cent in just 5 minutes.
• SSBs could enable vehicles to achieve ranges of up to 1,280 km (about 800 miles) per charge.
• The biggest upside: a dramatic leap in energy density and charging speed compared to current lithium-ion batteries.
Fortune Business Insights estimates that the global EV battery market size was valued at $59.06 billion in 2023; projected to grow from $67.78 billion in 2024 before spiking to $111.20 billion by 2032 – an annual growth of 6.4 per cent during the forecast period.
Patents
Every new breakthrough edges us closer to a seismic shift. The next-generation solid state batteries (SSBs) represents a major breakthrough. It's a revolution that is just getting started.
We’re not looking at a single leap, but a cascade of advances. Today, a huge effort is being poured into SSB development. The patent landscape for SSBs is getting bumped up.
A number of companies are leading the way. Asian companies currently lead in SSB patents: LG, Samsung and Toyota, hold more than 3,400 patents between them – about two-thirds of the world’s SSB patents. the next-gen batteries like SSBs could significantly advance the global EV market and the car-to-grid technology, where EVs not used for transport help stabilise the power grid.
This can trigger thermal runaway, where the battery gets so hot it ignites, releasing oxygen and extreme heat.
Temperatures can spike up to 900°C, causing dangerous, rapid fires. As we push for higher energy density batteries, the risk of such incidents increases, driving researchers to find safer solutions.
Global competition
Rapid progress is being made on next-gen batteries, with competing entities like CATL, BYD, CALB and universities like Stanford and Harvard, are going all in SSB development.
Amid this race, breakthroughs have been reported.
For example, Harvard’s John A. Paulson School of Engineering and Applied Sciences (SEAS) has reported in January a solid-state breakthrough: a battery that can be charged and discharged at least 6,000 times — more than any other pouch battery cell, as per Electrek.
SSB technology continues to undergo refinement by a diverse industrial groups and universities looking at a huge payoff. The minimum target: doubling of energy densities of existing batteries.
Leaders
CATL, the world’s largest battery manufacturer, is spearheading efforts in SSB development. In 2023, the company was testing 20 amp-hour samples of sulfide-based solid-state batteries.
These samples represent the first step toward mass production, with the company targeting small-scale production by 2026.
If successful, these batteries will allow EVs to charge quicker, last longer, and become more efficient overall.
Solid-state battery advantages
The advantages of solid-state batteries are not only theoretical. CATL has already demonstrated breakthroughs with lithium-iron phosphate (LFP) and sodium-ion batteries that have been mass-produced and deployed in vehicles, validating their claims.
However, challenges remain.
Mass-producing solid-state batteries while ensuring safety and performance under real-world conditions poses a major challenge for manufacturers.
Progress in solid-state batteries
The rapid progress in this field is setting the stage for the next generation of electric cars, making them more attractive than ever to consumers.
As electric vehicles become faster, more efficient, and accessible, the internal combustion engine’s dominance in the automotive industry is increasingly under threat.
By 2027, a new battery technology twice better than the popular lithium-ion batteries current found in most EVs and mobile devices, could come out of factories – significantly helping save the planet.
One of these advances might just trigger a “Kodak moment” or a “Nokia collapse” in the energy market. When it happens, the disruption will be massive, reshaping the landscape in an unprecedented way.
SSB developers
Industry estimates show SSBs could go into cars from as early as 2025, but with commercial-scale application from 2027.
Panasonic is actively developing its own SSB technology. However, unlike some of its competitors, Panasonic’s initial focus is not on EVs.
Instead, the company aims to introduce solid-state batteries for drones and industrial robots – by around 2029. Panasonic, a major battery supplier for Tesla, has made progress in addressing common issues such as the limited usage life of solid-state batteries.
Their approach involves enhancing the battery’s durability, which is crucial for high-cycle applications.
Meanwhile, Chinese, Japanese, Korean and European battery makers are all actively involved in the development of solid-state batteries, with varying commercialisation timelines, but mostly set for later this decade.
Here’s what we know so far on latest SSB developments:
CATL: The largest EV battery manufacturer globally, CATL is targeting the small-scale production of its solid-state batteries by 2027. They have been investing in R&D for over a decade and aim to achieve significant advancements in energy density, potentially up to 500 Wh/kg. However, challenges related to manufacturing scalability and cost remain as hurdles for mass production, as per electrive.com
QuantumScape: Based in the US, QuantumScape is a key player in SSB development. They have made significant strides in durability testing and have developed batteries that can withstand over 6,000 charge cycles. Their partnership with Volkswagen is aimed at integrating these batteries into electric vehicles.
BYD: As part of its solid-state battery initiative, BYD is collaborating within the China All-Solid-State Battery Collaborative Innovation Platform (CASIP). This consortium includes major Chinese battery players like CATL, CALB, and BYD’s subsidiary, FinDreams. The focus is on overcoming technical barriers and setting up a supply chain, with commercial-scale production likely to begin around 2030, according to Carscoops.
CALB: China Aviation Lithium Battery (CALB), another key member of the CASIP, is also gearing up for solid-state battery development. Like its peers, CALB is expected to advance towards commercialisation within the next decade, driven by collaborative research efforts and technological improvements as part of China’s broader push to lead in this new battery technology, according to Carscoops.
Toyota: Toyota has heavily invested in solid-state battery research. Their focus is on improving energy density and enhancing safety. Toyota aims to bring these batteries to market in their next generation of electric vehicles by the late 2020s.
Harvard University: Harvard has been pioneering in the academic research of solid-state battery technology. They have developed innovative designs that promise enhanced cycle life and faster charging capabilities, positioning them as leaders in the research domain alongside industrial players, according to the university.
Stanford University: Several research groups at Stanford are actively exploring innovations in solid-state battery research, focusing on enhancing the performance and scalability of solid-state electrolytes and lithium-metal anodes. The Dauskardt Group at Stanford is working on scalable designs for solid-state batteries, aiming to replace traditional liquid electrolytes with solid materials to boost energy density.
StorageX: This is a collaboration between Stanford and industrial partners. Researchers like Yi Cui, a prominent figure in the field of battery science at Stanford, are deeply involved in projects aimed at developing new solid electrolytes and exploring their fundamental properties.
For 165 years since the invention of lead acid batteries (LABs, in 1859) – they still start our internal combustion engine vehicles – LABs have dominated till today.
In the 1950s, a faster pace of innovations kicked in, when nickel/zinc batteries came out, followed by sodium/sulphur-based batteries in the 1980s.
In the 1990s, following John B. Goodenough’s invention of lithium-ion batteries (Li-ion) and its commercialisation by Sony, everything changed.
In the 2010s, Li-ion delivered up to 10 times the energy density (up to 340 Wh/kg) offered by LABs ( which remained unchanged at about 35 Wh/kg).
Common battery types and their energy density:
There are several different types of rechargeable batteries with a variety of energy densities reflective of their internal chemistry.
- Lead acid battery: 30-50 Wh/kg
- Nickel-cadmium battery: 45-80 Wh/kg
- Nickel-metal hydride battery: 60-120 Wh/kg
- Lithium-ion battery: 50-260 Wh/kg
- Lithium-iron phosphate battery: 90-160 Wh/kg
- Solid-state battery: 400-500 Wh/kg
Energy density vs power density: Energy density is often confused with power density, so it is important to understand the distinction between the two. Power density is the measure of how quickly the energy can be delivered, rather than how much stored energy is available.
Takeaways
- Disruption: Innovations in battery chemistry, alongside computing, AI and robotics have dramatically changed the global energy market.
- The race is on to overcoming the challenges of manufacturing and scaling the optimum energy storage technology.
- From 2025, SSBs could start seeing commercialisation, with broader applications likely in the early 2030s.
- This will have profound implications for how humanity produces, stores and uses energy.