Contemporary Amperex Technology Co., Limited

BEIJING, April 21, 2026 /PRNewswire/ -- CATL today hosted its Super Technology Day in Beijing, unveiling third-generation Shenxing Superfast Charging Battery, third-generation Qilin Battery, Qilin Condensed Battery, second-generation Freevoy Super Hybrid Battery, Naxtra Sodium-ion Battery and a fully integrated supercharging and battery-swapping solution. These innovations are designed to address diverse mobility needs across different usage scenarios.

At the event, Dr. Wu Kai, Chief Scientist of CATL, systematically elaborated on the respective strengths, limitations, and development pathways of different chemistries. He noted that LFP is nearing its theoretical energy density limit, making it better suited for a technology roadmap centered on extreme fast charging to achieve optimal balance. NCM's high energy density keeps it at the forefront of global competition — underscoring that energy density remains the core metric for leadership. Sodium-ion batteries offer broad potential for extreme temperatures and energy storage applications. Whether from the perspective of differentiated consumer needs, or from the viewpoints of energy security and social development, the lithium-ion battery industry must pursue coordinated development across multiple chemical systems.

Robin Zeng, Chairman and CEO of CATL, emphasized at the conference that industrial innovation must be driven by a rigorous scientific spirit. For Chinese technology to go global, it relies not just on speed and scale, but on the quality of innovation, the ability to validate, and the credibility of the brand.

Third-Generation Shenxing Superfast Charging Battery: Making Superfast Charging and Ultra-Long Lifespan No Longer a Trade-Off

From an electrochemical standpoint, boosting charge rates while protecting battery lifespan hinges on one primary factor: temperature rise, not trickle current. As the Arrhenius equation shows, a 10°C increase in battery temperature can roughly double the rate of internal side reactions—an effect that can significantly shorten cycle life.

The third-generation Shenxing Superfast Charging Battery addresses heat generation and dissipation through three major measures: reduced heat production during operation, stronger thermal propagation, and higher precision control. As a result, after 1,000 complete cycles, the battery's capacity retention remains above 90%, achieving an optimal balance between extreme superfast charging and ultra-long service life.

The latest third-generation Shenxing Superfast Charging Battery has reached what is claimed to be the industry's strongest capability: an equivalent 10C and a peak 15C charging rate. Charging from 10% to 35% SOC (State of Charge) takes just 1 minute; from 10% to 80% SOC takes 3 minutes and 44 seconds; and from 10% to 98% SOC takes 6 minutes and 27 seconds. Even at −30°C in extreme cold conditions, charging from 20% to 98% SOC takes about 9 minutes.

In addition, by combining battery self-heating technology with a fully integrated supercharging and battery-swapping network, the system is designed to enable low-temperature superfast charging that is not limited by charging piles—offering both fast charging and battery swapping.

Third-generation Qilin Battery: Lighter, Stronger, More Premium, Redefining EV Excellence

Historically, achieving long range in premium EVs with LFP batteries has relied on simply adding more capacity — an approach that inevitably compromises vehicle lightweighting.

The third-generation Qilin Battery is designed for premium long-range EVs, achieving a cell energy density of 280 Wh/kg and enabling 1,000 km range while supporting 10C superfast charging.

The battery delivers 3 MW peak power, doubling the output of the second-generation Qilin track battery which competed on the Nürburgring (1,330 kW).

The entire battery pack weighs only 625 kg. Compared with equivalent LFP systems, this represents a weight reduction of 255 kg and space savings of 112 litres. The lightweighting metrics deliver exceptionally significant benefits:

• Energy consumption per 100 km decreases by more than 6%, saving approximately 0.78 kWh per 100 km. Across a fleet of one million vehicles travelling 20,000 km annually, this equates to 156 million kWh in electricity savings and a reduction of 78,500 tonnes of CO₂ emissions.
• Performance and safety improvements include a 0.6–second reduction in 0–100 km/h acceleration, a 12% shorter overtaking risk window, an 8% higher moose test speed, a 6.5% lower body roll angle, a 15–25% gain in obstacle avoidance capability, and approximately 1.44 metres shorter braking distance.
• Durability is enhanced, with chassis component life extended by 40% and tyre life by over 30%, increasing replacement intervals by at least 10,000 km. The 112 litres of space saved can increase cabin headroom by at least 18 mm.

Building on the national standard for NP (No Thermal Propagation), safety is strengthened through "thermal-electrical separation", with each cell incorporating an independent sealed exhaust channel to isolate thermal events and prevent propagation, ensuring "heat takes the heat path, electricity takes the electrical path". 

Qilin Condensed Battery: Aviation-Grade Technology Applied to Passenger Vehicles for the First Time

The Qilin Condensed Battery applies aviation-grade technology to passenger vehicles for the first time, achieving 350 Wh/kg cell energy density and 760 Wh/L volumetric energy density — setting a new record for mass-produced batteries. This enables 1,500 km range for sedans and over 1,000 km for large SUVs, with pack weight controlled within 650 kg.

The condensed battery features a high-nickel cathode and low-expansion silicon-carbon anode, boosting energy density by 50 Wh/kg. Its first-ever aviation-grade titanium alloy case reduced thickness by 60% and weight by 30%, while tripling unit strength and delivering an additional 20 Wh/kg in energy density.

The technology builds on CATL's electric aviation programme, where 500 Wh/kg systems have completed maiden flight validation on 4-tonne aircraft, with further validation underway on aircraft exceeding 8 tonnes.

Replacing liquid electrolyte with a condensed system eliminates risks associated with leakage and combustion, achieving "no liquid to leak, no liquid to ignite". At the same time, CATL has adopted a new composite current collector that acts as a fast self-fusing fuse in extreme cases of internal short circuits.

Second-generation Freevoy Super Hybrid Battery: Bringing Hybrids into the 600 km Pure Electric Era

The second-generation Freevoy Super Hybrid Battery extends all-electric range to up to 600 km and standardises 10C superfast charging. It pioneers a "super hybrid technology" that integrates LFP and NCM materials through gradient-uniform mixing, with the olivine crystal structure of LFP serving as the core backbone, enabling a uniform hybrid of LFP and NCM materials at the powder particle level.

This achieves an energy density of 230 Wh/kg and increases range by over 15% without increasing pack weight compared with single LFP systems. This enables full coverage from mainstream family use to high-end, all-round hybrid scenarios, delivering optimal solutions across diverse applications.

The LFP version delivers up to 500 km pure electric range, enabling a "once-a-week charging" experience for daily commuting. The NCM version further extends pure electric range beyond 600 km, with total vehicle range exceeding 2,000 km, enabling a seamless dual-use experience for both daily electric driving and long-distance travel.

The system delivers 1.5 MW of instantaneous power at full charge and maintains 1.2 MW at 20% SOC, addressing power degradation in low-charge conditions. In off-road scenarios requiring over 350 kW output, the system provides more than three times the required power, ensuring consistent performance even at low charge levels.

Safety features include a reinforced bottom coating capable of withstanding 1,500 joules of impact energy (ten times the national standard) and waterproof sealing that allows continuous immersion in 2 metres of water for over 200 hours without performance degradation.

Naxtra Sodium-ion Battery: Achieving GWh-scale Sodium-ion Industrialisation

The Naxtra Sodium-ion Battery marks CATL's transition from laboratory breakthrough to large-scale manufacturing. By systematically overcoming hundreds of engineering challenges, CATL has achieved GWh-level industrialisation.

In 2026, CATL successfully addressed four key industry bottlenecks for sodium-ion mass production—extreme water control, gas generation in hard carbon, aluminium foil adhesion, and self-forming anode systems—paving the way for reliable, large-scale deployment. The Naxtra Sodium-ion Battery is set to enter full-scale mass production by the end of 2026.

Integrated Supercharging and Battery-swapping Network: A Unified Replenishment Architecture

CATL also introduced an integrated supercharging and battery-swapping network, designed as a unified system rather than separate solutions, built on three complementary pillars—home charging, public charging, and battery swapping—to define the optimal energy replenishment ecosystem. All passenger vehicle "Choco-Swap" and heavy truck "QIJI" swapping stations will be equipped with Shenxing supercharging systems, enabling true charge–swap synergy, where each station serves both as a battery-swapping node and a high-power charging hub.

The integrated charge–swap stations feature shared compact substations and charging modules, reducing energy conversion steps and lowering overall power loss by more than 13 percentage points compared with conventional storage-equipped charging stations. In emergency scenarios, station batteries can discharge directly to charging piles, driving equipment utilization rate above 85%. This enables a service capacity of 3× per parking space compared with conventional storage-equipped charging stations, while the fixed investment cost of the supercharging segment is reduced to only one-fifth of comparable systems.

CATL launched the Choco-Swap #26 battery, featuring an 800V high-voltage architecture. The first release includes a 75 kWh version, with higher-capacity variants to follow, fully compatible with B- to C-segment 800V vehicles. With this launch, the Choco-Swap system will extend its coverage to a complete vehicle matrix from A0 to C-segment models.

In terms of network deployment, CATL plans to build 4,000 integrated charge–swap stations by the end of 2026, covering nearly 190 cities and a nationwide highway network spanning 12 vertical and 11 horizontal corridors. To date, the Choco-Swap network has already built 1,470 stations across 99 cities, with scaling continuing to accelerate.

Together with automakers and energy partners, CATL will co-develop a "charge–swap sharing network" based on technology sharing, seamless connectivity, and joint investment. Initial partners include Changan, Chery, GAC, Seres, SAIC-GM-Wuling, and BAIC, with a target of building over 100,000 shared energy replenishment facilities by the end of 2028.

Advancing full-scenario energy solutions

From five battery products covering the full material spectrum to an integrated supercharging and battery-swapping network, CATL has established a complete value chain from battery products to infrastructure.

CATL will continue to invest in advanced research, large-scale manufacturing and ecosystem collaboration to accelerate the transition from single-point innovation to full-scenario energy solutions, ensuring the benefits of technological progress are accessible across all mobility use cases.

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NINGDE, China, Feb. 4, 2026 /PRNewswire/ -- Dr. Robin Zeng, Chairman and CEO of CATL, delivered a speech about the future of energy at the World Laureate Summit and the World Governments Summit in Dubai, the UAE on Feb. 3. Full text below:

Throughout human history, energy has been the driving force behind civilization's growth. Every major leap in human development has been accompanied by an energy revolution. Today, we are experiencing another revolutionary energy shift, one comparable to humanity's transition from hunter-gatherers to agricultural societies -- from an era where we track down and gather fossil fuels, to one where we can harvest energy in wind and solar farms and store it in batteries.

This revolution is enabled by science and technology progress, which delivers practical solutions and drives down costs. According to the IEA and BNEF, over the past decade, the cost of LFP batteries and solar has fallen by about 80%. Sustainable energy solutions have evolved from being technically feasible to becoming an economically compelling choice.

CATL is enabling renewable energy to achieve true economic competitiveness across a range of applications. In the mining sector, solar-plus-storage systems powered by CATL have been deployed in Chile and the Democratic Republic of the Congo, supplying electricity to remote operations at about one-fourth the cost of diesel generators.

A similar transformation is underway in industrial applications. In Pakistan, the rapid growth of distributed solar, combined with CATL's energy storage solutions, is providing reliable power to local cement plants, cutting electricity costs by half.

In California, we see what future power systems will look like at the grid scale. As storage capacity expands, the "duck curve" created by high renewable penetration has been significantly eased. In 2025, the grid recorded more than 1,800 hours when clean energy met or exceeded total electricity demand, showing what becomes possible when renewables and storage grow together.

These developments point to a broader reality: in many regions, clean energy is being adopted not just for climate goals, but also because technological progress has made it the most commercially viable option.

We are embracing the profound shift towards a net-zero energy era. The future energy system, to my mind, can be defined by three words: distributed, intelligent, circular.

First, distributed power systems, which include renewable generation and advanced battery storage, will mushroom across the world, especially in areas with weak grid infrastructure. This will replace a lot of fossil fuel energy, which is centralized and relies heavily on large-scale power plants and a strong grid.

However, a high proportion of renewable energy introduces new challenges to the stable operation of power systems. To address those challenges, CATL has developed an innovative high-voltage grid-forming energy storage technology, which can act as a stabilizer for zero-carbon energy systems. It can provide grid frequency regulation, reactive power compensation, damping control, and system inertia support. It also offers excellent black-start capabilities, which are crucial in the case of large-scale blackouts, like the one hit Spain last year.

This technology has been successfully validated in engineering, and in China we are applying this technology to build an off-grid industrial park, which is powered entirely by wind, solar, and storage to supply a 40GWh battery plant. It showcases how advanced energy technology can create a net-zero power system.

Beyond being distributed, future energy systems will be more intelligent. They will be able to handle vast amounts of data and adjust to fluctuations in renewable power generation and consumption. Advanced AI-driven scheduling and optimization will be required to balance energy supply and demand. For instance, we use AI to enhance energy system management for SenseTime's AI Data Center in Shanghai, helping manage the fluctuating energy demand of computing tasks.

Thirdly, circular economy is crucial for achieving zero-carbon energy. Unlike fossil fuels, which are burned upon use, materials for zero-carbon energy systems can be recycled. CATL has been at the forefront of this effort, and we have achieved the highest recovery rates in the industry—99.6% for nickel and cobalt, and 96.5% for lithium. To build a stable, sustainable supply of critical raw materials, we are also working closely with NGOs and industry peers to promote a circular economy in the sector.

Driven by continued progress in zero-carbon technologies, a sustainable energy era is no longer a distant vision — it is approaching rapidly. In my estimate, 2030 will mark the true beginning of the sustainable energy era.

How can we get there? My answer is: science shows us what is possible, but engineering and manufacturing determine how fast we get there.

Basic science remains the ultimate source of transformation. Breakthroughs in material science, artificial intelligence, and new energy systems will continue to shape what the future can look like. To be honest, with today's technologies, we may have solved less than 30% of what a fully sustainable energy system require. Many disruptive technologies have yet to emerge, and much foundational research still lies ahead.

For technology to truly change the world, it must move beyond labs and be deployed at scale. Today, we have made scientific and technological breakthroughs in frontier areas such as condensed batteries, solid-state batteries, and perovskite solar batteries. Yet there is still much more to do to scale these innovations from the lab to the market. That is why we are investing heavily in R&D – more than all other players in the industry combined.

While fighting global warming appears to be a climate issue, it is in essence an energy issue, and fundamentally, a development issue. We believe international cooperation is the most efficient way to tackle it, and we are willing to share battery technologies and experiences with the world. We have evolved from exporting batteries in the early days, to "local production, for local markets" now. We are also licensing technologies to our partners to help them build their own battery plants.

To accelerate the transition to a sustainable energy era, we need to scale up advanced energy technologies in a more efficient and affordable manner globally. However, in some markets, in our experience, building and equipment regulations are the cause of higher cost of production. I would like to propose a solution: setting up special economic zones that adopt similar regulations of building and equipment which are practiced in China. This will quickly scale up productivity, as it has been proven successful in China.

Ladies and gentlemen, a recent study by Columbia University projects a 1.7 degrees C temperature rise above the pre-industrial level in 2027. To tackle global warming, we need to take immediate action to build a sustainable energy system. This requires technology breakthroughs, courage and wisdom.

As a pioneer of the energy transition, CATL is willing to work more closely with the scientific community, governments, businesses, and anyone who is committed to the mission. Let's work together towards a net-zero energy future, and leave a healthy, green Earth for future generations to come.

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