Year: 2026

ZELIO E-Mobility, a rapidly growing electric two-wheeler brand in India, is set to introduce two new high-speed electric scooters by the second quarter of 2026. Aimed at urban commuters, professionals, students, and eco-conscious riders, these new models promise enhanced performance, cutting-edge technology, and a robust design. The company’s commitment to sustainability and innovation continues to shape India’s evolving electric mobility landscape.

What Sets ZELIO’s New High-Speed Electric Scooters Apart?

ZELIO’s upcoming high-speed electric scooters will feature smart connectivity, improved range efficiency, and stronger chassis engineering to tackle diverse Indian road conditions. These scooters are designed to offer enhanced performance and durability, addressing the growing demand for efficient and eco-friendly urban mobility solutions. ZELIO aims to provide not only high-speed performance but also convenience and sustainability in daily commutes.

The company’s earlier high-speed model, the ZELIO Mystery, has already garnered significant attention in the market, selling over 2,000 units since its debut. The Mystery is equipped with a 72V/29AH lithium-ion battery, offering a range of 100 km per charge and a top speed of 70 km/h. With the upcoming models, ZELIO plans to take performance to the next level, catering to the diverse needs of urban commuters and delivery businesses.

How Will ZELIO’s Upcoming Models Address India’s Last-Mile Delivery Challenges?

ZELIO E-Mobility’s new high-speed scooters will play a crucial role in India’s last-mile delivery ecosystem. With the increasing demand for efficient delivery services, especially in urban areas, these new models are designed to meet the needs of delivery agents, offering a blend of power, range, and reliability. Their enhanced design and performance will provide a seamless solution for logistics companies, ensuring timely and eco-friendly deliveries.

By focusing on the needs of last-mile delivery, ZELIO is helping shape the future of electric mobility in India, which is seeing a surge in demand for EVs, particularly for commercial use in the delivery sector. With these new scooters, ZELIO is positioning itself as a key player in this rapidly growing market.

How Has ZELIO E-Mobility Gained Traction in the EV Market?

Since its inception in 2021, ZELIO E-Mobility has made significant strides in India’s electric vehicle market. The company has served over 200,000 riders and operates through 400 dealerships. This strong network has allowed ZELIO to reach a wide audience and ensure reliable service and after-sales support for its customers. With plans to expand its network to 1,000 outlets by the end of 2025, ZELIO is positioning itself as a leader in the Indian EV space.

The brand’s focus on performance-oriented, feature-rich scooters has resonated with both individual and business customers, especially with the success of the ZELIO Mystery. By continuing to innovate and expand its portfolio, ZELIO is poised to maintain its competitive edge in the ever-growing EV market.

What Role Does ZELIO E-Mobility Play in India’s EV Revolution?

ZELIO E-Mobility is playing a vital role in India’s ongoing electric vehicle revolution, particularly in the two-wheeler segment. As the country transitions toward greener transportation solutions, ZELIO’s affordable and high-performance electric scooters are helping to reduce carbon emissions and dependence on fossil fuels. The introduction of new models with improved technology and efficiency will further accelerate this transformation.

With India’s growing focus on sustainable mobility, ZELIO is at the forefront of meeting the needs of eco-conscious riders and businesses. By making electric scooters more accessible and reliable, ZELIO is helping to make electric mobility an attractive alternative to traditional vehicles.

ZELIO Expert Views

“At ZELIO E-Mobility, we believe that the future of transportation in India lies in sustainable, efficient, and high-performance electric vehicles. Our upcoming models are designed to meet the diverse needs of Indian riders, from daily commuters to businesses relying on last-mile deliveries. With our continued focus on innovation and performance, we are excited to play a leading role in India’s electric mobility future.”
— Mr. Kunal Arya, Co-Founder and Managing Director, ZELIO E-Mobility

Conclusion: The Future of Electric Mobility in India

ZELIO E-Mobility’s plans to launch two new high-speed electric scooters mark a significant step toward revolutionizing urban transportation in India. With a strong emphasis on sustainability, performance, and customer satisfaction, ZELIO is helping shape the future of electric two-wheelers in the country. As demand for eco-friendly mobility solutions continues to rise, ZELIO is poised to play a major role in India’s electric vehicle revolution.

FAQs

1. What are the key features of ZELIO’s upcoming high-speed electric scooters?

The upcoming models will feature smart connectivity, enhanced range efficiency, and stronger chassis engineering to handle diverse Indian road conditions.

2. How has ZELIO E-Mobility gained market traction in India?

ZELIO has served over 200,000 riders through 400 dealerships and plans to expand to 1,000 outlets by the end of 2025.

3. What is the top speed and range of ZELIO’s Mystery scooter?

The ZELIO Mystery offers a top speed of 70 km/h and a range of 100 km per charge.

4. How does ZELIO’s new scooter line benefit last-mile delivery businesses?

The new scooters are designed to meet the demands of last-mile delivery with powerful performance, extended range, and durability.

5. What is ZELIO’s role in India’s EV market?

ZELIO is helping accelerate India’s transition to electric mobility by offering affordable, high-performance electric two-wheelers.

Electric motorcycles have long been criticized for their limited range and slow charging times. However, recent innovations in battery technology and vehicle designs could soon change that. Solid-state batteries, like those showcased at CES 2026, promise faster charging and greater energy density, potentially revolutionizing electric motorcycles. This article will delve into the latest breakthroughs, including Verge Motorcycles’ solid-state battery and the futuristic JetBike, powered by electric jet propulsion.

What is Solid-State Battery Technology, and How Does It Benefit Electric Motorcycles?

Solid-state batteries are a next-generation power source that replaces the liquid electrolyte in traditional lithium-ion batteries with a solid electrolyte. This change offers several benefits, including higher energy density, faster charging times, and enhanced safety. Redway Battery, a leading manufacturer in the field, is working towards perfecting these battery technologies for various applications, including electric vehicles. Solid-state batteries are considered a game-changer for electric motorcycles, solving many issues associated with their current lithium-ion counterparts, such as the risk of overheating and limited charge cycles.

How Does Verge Motorcycles’ TS Pro Model Incorporate Solid-State Batteries?

The Verge TS Pro, unveiled at CES 2026, uses a 33.3 kWh solid-state battery, claiming an impressive 370-mile range on a single charge. What sets this model apart is its rapid charging capability, with Verge Motorcycles stating the TS Pro can gain up to 60 kilometers of range per minute of charging. This is a significant improvement over traditional lithium-ion-powered bikes, which often require hours to charge fully. Verge’s innovative hubless motor and solid-state battery design could be the future of electric motorcycles, combining high performance with efficiency.

What Makes the Verge TS Pro Stand Out in the Market?

The Verge TS Pro not only incorporates a solid-state battery but also features a sleek design and remarkable performance stats. With a torque of 737 foot-pounds, it promises acceleration and speed that rival gas-powered bikes. It also boasts a range of up to 370 miles and a fast-charging capability that can significantly reduce downtime. Verge’s commitment to pushing the limits of electric motorcycle technology makes it a pioneer in this space, attracting attention from both consumers and industry leaders.

Could Flying Motorcycles Become a Reality with the JetBike?

Another exciting development at CES 2026 is the JetBike by LEO Flight, a personal eVTOL (electric vertical take-off and landing) vehicle. While it is still in its early stages, the JetBike is designed to offer a new mode of transportation, using solid-state batteries to power its flight. Capable of reaching speeds up to 60 mph and flying up to 15 feet high, the JetBike introduces the idea of flying motorcycles, a futuristic concept that could soon become a reality. While it currently has a limited battery life of 10-15 minutes, the potential for further development makes it an intriguing prospect for personal air travel.

Why Are Solid-State Batteries the Key to Advancing Electric Motorcycles?

Solid-state batteries offer several advantages that make them a crucial development for electric motorcycles. These batteries have higher energy density, which translates to longer ranges for motorcycles, allowing riders to travel further on a single charge. Additionally, they charge much faster than conventional lithium-ion batteries, significantly reducing the downtime between rides. As these batteries become more mainstream, we can expect faster adoption of electric motorcycles, making them more viable as everyday transportation options. Redway Battery is already working on solid-state battery technologies to provide robust solutions for the future of electric mobility.

What Impact Will the Redway Battery Expertise Have on Electric Motorcycle Development?

As a trusted OEM lithium battery manufacturer, Redway Battery is playing a pivotal role in the development of next-generation energy solutions for electric motorcycles. The company’s years of expertise in producing LiFePO4 batteries have positioned them as a leader in the field of electric vehicle energy storage. Redway’s solid-state battery technology could significantly impact the electric motorcycle industry by offering batteries that are not only more efficient but also safer and longer-lasting. Their research and development efforts are helping to pave the way for a more sustainable and efficient future for electric motorcycles.

Redway Expert Views

“As the demand for electric motorcycles continues to rise, solid-state batteries are becoming essential to meet the evolving needs of the market. Our goal at Redway Battery is to provide the most advanced and reliable battery technologies to ensure that electric vehicles, including motorcycles, are safe, efficient, and capable of going the distance. With continued innovation, we’re excited to lead the way in battery solutions for the next generation of electric mobility.”
— Redway Battery Expert

Conclusion: Key Takeaways

Electric motorcycles are on the verge of a major breakthrough thanks to innovations in solid-state battery technology. Verge Motorcycles is leading the way with its TS Pro model, offering longer range and faster charging times, while the JetBike offers a glimpse into the future of flying motorcycles. As manufacturers like Redway Battery continue to develop more efficient and durable energy solutions, we can expect a significant shift toward electric vehicles in the coming years. For motorcycle enthusiasts, the future of electric rides looks brighter than ever.

FAQs

1. What is the range of Verge Motorcycles’ TS Pro?

The TS Pro offers a range of up to 370 miles on a single charge, thanks to its solid-state battery technology.

2. How long does it take to charge the Verge TS Pro?

The Verge TS Pro can charge up to 60 kilometers of range per minute of charging, making it incredibly fast compared to traditional electric motorcycles.

3. What is the advantage of solid-state batteries over lithium-ion batteries?

Solid-state batteries are safer, have higher energy density, and offer faster charging times compared to lithium-ion batteries, making them ideal for electric motorcycles.

4. Can flying motorcycles become mainstream?

While still in early development, flying motorcycles like the JetBike are gaining attention and could be the future of personal air travel.

5. How does Redway Battery contribute to the electric motorcycle industry?

Redway Battery’s expertise in lithium and solid-state battery technology is helping to develop more efficient, reliable, and long-lasting battery solutions for electric motorcycles.

CATL, the Chinese battery giant, is expanding its sodium-ion battery (SIB) offerings, highlighting a significant upgrade and diversification of its product line for 2026. The company is positioning sodium and lithium batteries to work together seamlessly across various applications, including energy storage and transportation.

What are the Advantages of Sodium-Ion Batteries Over Lithium-Ion Batteries?

Sodium-ion batteries (SIBs) offer distinct advantages over traditional lithium-ion batteries (LIBs). One of the primary benefits is their ability to perform in extreme temperatures, ranging from -40°C to 70°C. This makes them suitable for use in regions where lithium-ion batteries struggle with cooling or heating requirements. Furthermore, sodium-ion batteries are noted for their lower carbon footprint, superior safety features, and potentially lower costs due to abundant raw materials.

SIBs also support a range of applications that were previously out of reach for LIBs, including passenger vehicles, commercial vehicles, and energy storage systems. As CATL continues to improve their performance, SIBs are likely to become a staple in multiple industries.

How is CATL Enhancing Its Sodium-Ion Battery Applications?

CATL is broadening the scope of its sodium-ion batteries by expanding into key areas like energy storage, battery swapping systems, and transportation. Their newly developed Naxtra brand includes specialized products such as the “Sodium New Power Battery” for passenger vehicles and a robust 24V battery for heavy trucks.

These advancements aim to provide efficient, long-lasting power solutions in various sectors, with the added benefit of operating in extreme environments. CATL’s goal of a dual-battery approach, combining sodium-ion and lithium-ion technologies, is expected to dominate the future of battery storage and vehicle energy solutions.

What is the Expected Energy Density and Range of CATL’s Sodium-Ion Batteries?

CATL’s 2026 sodium-ion batteries promise an impressive energy density of up to 175 Wh/kg. This enables passenger vehicles to achieve a range of up to 500 kilometers on a single charge. The improved energy density allows for longer-lasting, more efficient batteries that are compatible with a variety of electric vehicles, from cars to heavy-duty trucks.

With these enhancements, sodium-ion batteries are expected to become an essential part of the global energy transition, complementing lithium-ion solutions in areas where their limitations once posed challenges.

How Could Sodium-Ion Batteries Impact the Cost of Energy Storage Solutions?

The lower production cost of sodium-ion batteries could significantly disrupt the current energy storage market. According to a report by the International Renewable Energy Agency (IRENA), the cost of sodium-ion battery cells is expected to drop to as low as $40/kWh in the near future. This presents a more affordable alternative to lithium-ion batteries, especially for large-scale storage applications.

Sodium-ion batteries are expected to be a strong competitor in the stationary storage sector, where cost-efficiency and scalability are crucial for widespread adoption. As demand for energy storage solutions increases, SIBs will play a key role in reducing overall system costs.

Redway Expert Views

“With advancements in sodium-ion technology, the battery industry is moving toward a more diverse and sustainable future. Companies like CATL, alongside manufacturers such as Redway Battery, are pioneering solutions that will not only enhance energy storage capabilities but also improve environmental impact and cost-effectiveness in the long run. The combined approach of sodium and lithium technologies will lead the charge in cleaner, more efficient energy systems.”

Conclusion: Key Takeaways and Future Outlook

As CATL continues to evolve its sodium-ion battery technology, we are witnessing a shift towards more sustainable, cost-effective energy storage solutions. The company’s strategic expansion into energy storage, transportation, and commercial applications positions it as a key player in the battery market for 2026 and beyond.

Sodium-ion batteries, with their wide temperature range, enhanced safety, and superior carbon footprint, present a promising alternative to lithium-ion batteries. The potential for cost reductions, alongside their versatility, makes them an attractive option for industries across the globe.

Frequently Asked Questions (FAQs)

1. What is the energy density of CATL’s sodium-ion batteries?

CATL’s sodium-ion batteries are expected to achieve an energy density of up to 175 Wh/kg, enabling longer-range applications, including passenger vehicles and energy storage solutions.

2. Can sodium-ion batteries be used in cold or hot climates?

Yes, sodium-ion batteries have operational temperature ranges from -40°C to 70°C, making them suitable for extreme climates where lithium-ion batteries may not function efficiently.

3. What industries can benefit from sodium-ion batteries?

Sodium-ion batteries can be used in various industries, including energy storage, passenger vehicles, commercial vehicles, and battery swapping systems.

4. How does the cost of sodium-ion batteries compare to lithium-ion batteries?

Sodium-ion batteries are expected to be more affordable due to lower material costs, with projections suggesting a price drop to around $40/kWh in the near future.

5. Will sodium-ion batteries replace lithium-ion batteries?

Sodium-ion batteries are not expected to replace lithium-ion batteries but will supplement them, particularly in applications where their unique advantages—such as temperature tolerance and cost-efficiency—can be leveraged.

The Toshiba SCiB™ 24V battery pack is a lithium-ion energy solution designed to replace conventional lead-acid batteries in vehicles, marine vessels, and industrial machinery. With high safety, long life, and robust performance in demanding environments, it offers scalable configurations, efficient energy output, and reduced environmental impact, enabling reliable, sustainable power for diverse mobility and industrial applications.

What Are the Key Features of the Toshiba SCiB™ 24V Battery Pack?

The SCiB™ 24V battery pack features 20Ah-HP SCiB™ cells and is engineered for straightforward replacement of 24V lead-acid units following Japanese Industrial Standard D23 (JIS D 5301). Key features include:

• High Durability: Exceptional resistance to vibration, shocks, and temperature fluctuations.

• Long Life: Extended cycle life reduces maintenance needs.

• Environmental Efficiency: Lightweight, low emissions, and recyclable components.

• Flexible Configurations: Can be connected in series or parallel to meet power requirements up to 5.76kWh.

• Waterproofing: Certified IPX7 and IPX9K for marine and outdoor applications.

These attributes make the battery ideal for electric boats, trucks, construction machinery, and other high-load operations.

How Is the SCiB™ 24V Battery Pack Used in Yamaha Motor’s “e-Float Terrace”?

Yamaha Motor equips its sightseeing electric boat “e-Float Terrace” with twenty-four SCiB™ 24V battery packs arranged in two series of 2 and 6 in parallel, achieving 48V and 11.52kWh total output. This setup powers Yamaha’s proprietary HARMO electric propulsion system, providing smooth, efficient, and environmentally friendly cruising along Yokohama’s Minato Mirai seafront.

The adoption of these lithium-ion batteries enables lower emissions, quieter operations, and reduced maintenance compared with traditional lead-acid solutions, highlighting a shift toward sustainable marine mobility.

Which Industries Can Benefit from SCiB™ 24V Battery Packs?

SCiB™ 24V battery packs serve multiple sectors, including:

This versatility makes it a valuable solution for companies seeking reliable, sustainable power.

Does Redway Battery Offer Similar High-Performance Lithium-Ion Solutions?

Yes, Redway Battery provides LiFePO4 batteries designed for industrial and automotive applications. With over 13 years of expertise and advanced factories, Redway ensures:

• Custom OEM/ODM solutions for forklifts, golf carts, RVs, telecom, solar, and energy storage.

• High-performance, durable, and safe battery packs for demanding operational environments.

• Full engineering support with automated production and 24/7 after-sales service.

By combining reliability and innovation, Redway Battery delivers performance comparable to SCiB™ solutions, emphasizing safety, long life, and efficiency.

Redway Expert Views

“High-performance lithium-ion batteries are redefining industrial mobility and energy storage. At Redway Battery, we focus on delivering durable, scalable, and safe LiFePO4 solutions that reduce environmental impact while maintaining consistent performance under demanding conditions. Our goal is to support customers worldwide with tailored solutions, ensuring energy efficiency, reliability, and long-term cost savings across multiple sectors.”

How Can Series and Parallel Configurations Optimize Battery Performance?

SCiB™ 24V batteries can be connected in series to increase voltage or in parallel to expand capacity. For instance:

• Series Connection: Two 24V units in series yield 48V.

• Parallel Connection: Six units in parallel reach higher energy storage, up to 5.76kWh.

This flexibility enables customization for applications ranging from electric boats to industrial equipment, providing the exact power output and runtime required.

Conclusion

The Toshiba SCiB™ 24V battery pack represents a new standard for lithium-ion energy in automotive, marine, and industrial fields. Its long life, high safety, and adaptable configurations allow seamless replacement of lead-acid batteries while reducing environmental impact. Companies like Redway Battery offer parallel solutions with OEM customization, ensuring reliable and sustainable energy across sectors. Embracing advanced lithium-ion technology is essential for future-ready mobility and industrial operations.

FAQs

Q1: Can SCiB™ 24V batteries replace all lead-acid batteries?
A1: They are compatible with many 24V lead-acid systems, especially where JIS D23 standards are followed.

Q2: How long do SCiB™ 24V batteries last?
A2: SCiB™ batteries offer extended cycle life, often lasting several times longer than traditional lead-acid units.

Q3: Are SCiB™ 24V batteries safe for marine use?
A3: Yes, they are certified IPX7/IPX9K, making them waterproof and vibration resistant, ideal for boats.

Q4: Does Redway Battery provide customization?
A4: Yes, Redway Battery offers full OEM/ODM customization to meet specific voltage, capacity, and application requirements.

Q5: Can SCiB™ batteries be scaled for higher energy needs?
A5: Yes, series and parallel configurations allow scalable voltage and capacity, up to 5.76kWh or more depending on the setup.

CATL is scaling up its sodium-ion battery (SIB) product range in 2026, expanding applications to energy storage, battery swap systems, passenger vehicles, and commercial vehicles. With energy densities up to 175 Wh/kg, extreme temperature operability (-40 °C to 70 °C), and a lower carbon footprint, SIBs are positioned to complement lithium-ion batteries, creating a “dual-star” approach in battery technology.

How Is CATL Expanding Sodium-Ion Applications?

CATL’s 2026 plans include deployment across multiple sectors:

• Energy Storage: Grid and distributed storage systems benefit from the low-cost, durable SIBs.

• Battery Swap Systems: Commercial electric vehicles can leverage fast-replaceable SIB modules.

• Passenger Vehicles: Sodium-ion batteries support ranges of up to 500 km, with reliable performance in extreme temperatures.

• Commercial Vehicles: 24V heavy-truck starter batteries offer rugged, high-current performance for industrial applications.

Why Are Sodium-Ion Batteries Gaining Strategic Importance?

SIBs provide key advantages over traditional lithium-ion batteries (LIBs) for certain applications:

• Broader temperature range supports cold winters and hot summers.

• Reduced carbon footprint and enhanced safety.

• Competitive energy density (up to 175 Wh/kg) for mid-range mobility and stationary storage.
  This positions sodium-ion technology as a cost-effective, environmentally friendly alternative for high-volume commercial adoption.

What Are the Market Dynamics Affecting Sodium-Ion Batteries?

• Cost Trends: IRENA forecasts SIB cell costs could drop to $40/kWh.

• Complementary Role: Sodium-ion is expected to supplement, not replace, lithium-ion batteries, optimizing supply chains and deployment flexibility.

• Lithium Pricing: Lower-cost LFP battery packs fell to $70/kWh in 2025, influencing the comparative value of SIBs for stationary storage.

• Supply Chain Challenges: Raw material availability and production scale remain critical factors for market growth.

Which Manufacturers Are Leading the Sodium-Ion Segment?

CATL is the front-runner in commercializing sodium-ion technology, introducing the Naxtra brand with:

• Sodium New Power Battery: Optimized for passenger vehicles.

• Sodium New 24V Heavy Truck Start-Park Integrated Battery: Ruggedized for commercial and industrial vehicles.

Other major players like BYD and Huawei are also actively exploring sodium-ion applications, though CATL leads in large-scale deployment and pilot projects.

How Will Sodium-Ion Batteries Complement Lithium-Ion Systems?

CATL’s “dual-star” approach envisions:

• Lithium-ion batteries covering high-energy, long-range applications.

• Sodium-ion batteries handling temperature extremes, high-current starts, and cost-sensitive stationary storage.
  This synergy allows businesses and utilities to optimize battery deployment based on application-specific requirements.

What Are the Future Outlook and Opportunities?

• Energy Storage Expansion: SIBs provide reliable, sustainable alternatives for grid-scale and distributed storage projects.

• Commercial Vehicle Integration: Heavy-duty fleets can benefit from lighter, temperature-resilient batteries with longer lifecycle performance.

• Battery Swaps & Microgrids: Rapidly replaceable modules support urban mobility and emergency power solutions.

• Cost Reduction: Ongoing R&D and scaling production are expected to further lower SIB costs, making them more competitive with lithium-ion options.

Conclusion

In 2026, CATL’s sodium-ion battery strategy positions SIBs as a complementary technology to lithium-ion batteries, supporting grid storage, commercial transport, and passenger EV applications. With strong thermal tolerance, environmental advantages, and declining costs, sodium-ion batteries are set to expand their role in energy storage and electrified mobility, forming a dual-battery ecosystem for diverse industrial and consumer applications.

The 24V starting lithium battery market is experiencing robust expansion, projected to grow from USD 193 million in 2025 to USD 332 million by 2032 at a CAGR of 8.2%. Driven by automotive, commercial, marine, and defense applications, these batteries offer high cranking power, long cycle life, lightweight construction, and enhanced energy efficiency compared to lead-acid alternatives.

How Are Automotive and Marine Applications Fueling Market Growth?

The adoption of 24V starting lithium batteries in commercial vehicles, passenger vehicles, and marine equipment is accelerating due to superior cranking performance and faster recharge times. Heavy-duty fleets, long-haul trucks, and boats benefit from weight reduction, lower maintenance, and improved fuel efficiency. The shift toward high-performance power solutions drives annual market growth of approximately 14%.

Why Is the Military and Defense Sector Important for Market Expansion?

Military applications demand lightweight, durable, and high-energy-density batteries for engines in armored vehicles and tactical equipment. Extended lifespans and minimal maintenance requirements make 24V lithium batteries strategically valuable. Defense procurement programs globally are supporting adoption, making these batteries crucial for mission-critical operations.

What Are the Key Market Challenges?

High initial costs, often 2.5–3 times higher than lead-acid batteries, limit adoption among price-sensitive buyers. Temperature sensitivity and cold-weather reliability concerns, despite advanced battery management systems (-30°C to 60°C), also pose adoption barriers. Supply chain vulnerabilities for lithium, cobalt, and nickel further affect production costs and market expansion.

Where Are the Market Opportunities?

Off-grid energy and renewable integration present significant opportunities. Lithium starting batteries are ideal for solar-powered RVs, boats, and remote installations. The marine lithium battery market alone is projected to reach USD 1.2 billion by 2027. Their compatibility with solar charging systems positions them as critical components in sustainable and resilient energy solutions.

Which Battery Chemistries and Capacities Are Leading?

LiFePO₄ dominates due to safety, thermal stability, and performance across temperature ranges. Other chemistries, including NCM/NCA and LiMn₂O₄, are gaining traction for higher energy density applications. The 50–100 Ah capacity range is most in demand, balancing power needs with weight savings for commercial vehicles, electric utility vehicles, and medium-duty trucks.

Who Are the Key Players in the Market?

The market is led by Asia-Pacific manufacturers, including LG Energy Solution, Samsung SDI, CATL, BYD, Camel Group, LYBATT, and Shenzhen Center POWER Tech. These players account for over 60% of global revenue and differentiate through cold cranking performance, cycle life, and ruggedized designs. Traditional lead-acid producers like Clarios are transitioning to lithium solutions to maintain relevance.

How Are Regional Markets Developing?

• North America: Dominated by heavy-duty vehicle adoption and advanced OEM partnerships. The U.S. leads in adoption for trucks and RVs, supported by regulatory incentives and early R&D investment.

• Europe: Growth driven by commercial vehicle electrification, luxury automotive demand, and stringent cold-weather performance standards. Germany and Scandinavia lead adoption.

• Asia-Pacific: Fastest-growing market, fueled by Chinese EV production, Japanese commercial vehicle manufacturers, and Australian mining sector demand.

• South America: Selective adoption in mining and agricultural machinery; cost factors limit broader penetration.

• Middle East & Africa: Focused on luxury vehicles, oil/gas equipment, and mining applications; lead-acid alternatives remain dominant in cost-sensitive segments.

What Are the Key Market Trends?

1. Rapid Growth: Driven by superior cranking power, lightweight design, and long cycle life.

2. Material Chemistry Evolution: LiFePO₄ dominates due to thermal stability and safety; NCM/NCA and other chemistries grow in high-density applications.

3. Strategic Partnerships: OEM collaborations accelerate adoption in commercial fleets.

4. Supply Chain Adaptation: Manufacturers diversify production locations to mitigate raw material volatility and tariff impacts.

5. Technology Innovation: Integrated battery management systems and telematics enhance performance, particularly in extreme climates.

Conclusion

The 24V starting lithium battery market is poised for sustained growth through 2032, driven by commercial vehicles, marine, and defense sectors. LiFePO₄ chemistries, mid-range capacities, and strategic OEM partnerships remain central to market expansion. While cost, temperature sensitivity, and supply chain challenges persist, opportunities in off-grid energy integration and renewable systems provide significant growth potential for manufacturers and stakeholders.

FAQs

Q1: What is the current market size of the 24V starting lithium battery market?
A1: USD 179 million in 2024, projected to reach USD 332 million by 2032.

Q2: What are the main advantages of 24V lithium starting batteries?
A2: Lightweight, faster recharge, high cranking power, long cycle life, and energy efficiency.

Q3: Which battery chemistries are most used?
A3: LiFePO₄ dominates, followed by NCM/NCA and LiMn₂O₄.

Q4: Who are the leading manufacturers?
A4: LG Energy Solution, Samsung SDI, CATL, BYD, Camel Group, LYBATT, and Shenzhen Center POWER Tech.

Q5: Which regions show the fastest growth?
A5: Asia-Pacific is the fastest-growing market, driven by China, Japan, and Australia.

The global automotive lead-acid battery market is projected to reach USD 35.291 billion by 2032, growing at a CAGR of 6.5% from 2026 to 2032. Demand is driven by the rise of new energy vehicles (NEVs), expanding vehicle fleets, and applications in energy storage. Lead-acid batteries remain essential for start-stop systems, auxiliary power, and low-voltage functions, offering cost-effective, reliable solutions despite the rise of lithium alternatives.

How Is the Growth of New Energy Vehicles Affecting Lead-Acid Battery Demand?

New energy vehicle adoption, particularly in China, is rapidly increasing, with production and sales exceeding 12.8 million units in 2025. While lithium batteries are the main power source, lead-acid batteries continue to support start-stop functions, auxiliary power, and low-voltage systems. Their integration into hybrid powertrains and energy recovery systems sustains market relevance, ensuring steady demand even in highly electrified vehicles.

What Role Does Vehicle Fleet Expansion Play in Market Demand?

China’s vehicle fleet reached 419 million units by the end of 2024. Lead-acid batteries, with an average replacement cycle of three years, generate substantial aftermarket demand. In 2024, over 80 million vehicles required replacement batteries, resulting in total demand of 112 million units and a domestic market value of RMB 17.655 billion. This growing vehicle base ensures long-term stability for the lead-acid battery market.

How Are Policy and Environmental Standards Supporting Market Growth?

Government policies, including China’s New Energy Vehicle Industry Development Plan (2021–2035), promote high-performance, long-life batteries and stricter environmental compliance. Regulations on low-lead content, improved electrolytes, and higher recycling rates drive technological upgrades. Subsidies and tax incentives reduce costs for manufacturers and buyers, stimulating further growth in both automotive and energy storage applications.

Where Are Lead-Acid Batteries Expanding Beyond Vehicles?

Energy storage applications are increasingly important due to renewable integration and grid balancing needs. Lead-acid batteries offer low cost, high safety, and mature technology. In 2024, they accounted for 75% of global starting batteries, and China’s backup power segment reached RMB 10.494 billion with 13.76 million kVAh production. They are widely applied in charging infrastructure, industrial energy storage, and distributed power systems.

What Technological Advancements Are Strengthening Lead-Acid Batteries?

Advances such as lead-carbon, AGM, and EFB batteries enhance energy density, cycle life, and safety. Their cost competitiveness remains high, with raw materials comprising over 80% of total costs, supporting exports (USD 3.903 billion from China in 2024). Continued R&D and adoption of innovative battery chemistries improve market positioning in price-sensitive and specific-use segments.

What Challenges Does the Market Face?

1. Substitution by Advanced Batteries: Lithium and sodium-ion technologies offer higher energy density and longer lifespans, reducing lead-acid market share in NEVs and premium applications.

2. Environmental Regulations: Stricter waste treatment and recycling standards raise production costs and operational complexity.

3. Overcapacity & Price Competition: Excess production capacity reduces utilization rates to 53% in some regions, pushing gross margins down from 18% in 2023 to 6.7% in early 2025.

4. Technological Lag: Lead-acid batteries deliver 300–500 cycles, far below lithium alternatives (>2,000 cycles), limiting appeal in long-life applications.

5. Automotive Transition: The electrification of vehicles and adoption of 12V lithium solutions gradually decrease traditional demand for lead-acid starting batteries.

Redway Expert Views

“Lead-acid batteries continue to play a vital role in both automotive and stationary energy storage markets. While lithium technologies dominate high-energy applications, lead-acid solutions remain indispensable for start-stop systems, auxiliary power, and low-voltage circuits. Manufacturers focusing on technological upgrades, recycling, and cost efficiency can maintain strong market relevance and capitalize on expanding NEV fleets and energy storage deployments globally.”

Conclusion

The automotive lead-acid battery market remains robust, supported by NEV growth, rising vehicle ownership, and energy storage demand. Technological advancements, policy support, and cost advantages provide opportunities, while substitution by lithium and regulatory pressures are key challenges. Strategic investments in recycling, performance improvements, and niche applications will sustain the market’s long-term growth.

FAQs

Q1: Why are lead-acid batteries still used in electric vehicles?
A1: They provide reliable start-stop, auxiliary, and low-voltage functions, complementing lithium main batteries.

Q2: How does policy support influence lead-acid battery growth?
A2: Policies encourage cleaner production, recycling, and performance standards, boosting adoption and technological upgrades.

Q3: What are the main challenges facing lead-acid batteries?
A3: Competition from lithium, environmental regulations, overcapacity, price pressures, and slower technological progress.

Q4: Can lead-acid batteries remain relevant in energy storage applications?
A4: Yes, due to cost-effectiveness, safety, and reliability for grid balancing, backup power, and distributed storage.

Q5: How does vehicle fleet expansion affect replacement demand?
A5: Growing fleets increase battery replacement cycles, ensuring stable aftermarket demand for lead-acid batteries.

Battery energy storage is transitioning from a niche solution to a central component of U.S. grid infrastructure. Record installations, growing renewable penetration, and the need for climate-resilient, reliable power are driving rapid deployment. Utilities and municipalities are implementing multi-gigawatt projects to balance supply, stabilize grids, and provide backup power, signaling sustained growth and contracting opportunities through 2026.

How Are Utilities Integrating Battery Storage into the Grid?

Utilities are increasingly relying on batteries to:

• Absorb excess solar and wind generation during midday surpluses.

• Supply energy during peak-demand periods or outages.

• Reduce reliance on fossil fuel peaking plants.

• Enhance grid reliability and frequency regulation.

Integration of storage helps utilities manage renewable intermittency and improves operational flexibility across transmission and distribution networks.

What Are Some Notable 2026 Battery Storage Projects?

California – Sacramento Municipal Utility District:

• 160 MW / 640 MWh system on a decommissioned nuclear site.

• 100 battery containers with stormwater control, security, and maintenance areas.

• Supports renewable integration, peak load management, and emissions reduction.

• Construction begins June 2026.

Ohio – Cuyahoga County & Cleveland-Painesville Partnership:

• $129.4 million EPA-funded project replacing coal-fired generator with 10–20 MW battery storage and ~63 MW solar.

• Targets climate resilience, site redevelopment, and grid stability.

• Staged construction: 2026–2028.

Florida – Tallahassee Electric and Gas Utility:

• $39 million utility-scale battery system at Birmingham Street Substation.

• Backing four critical community facilities with 10–25 MW capacity.

• Includes storm-hardening, automated switching, and cyber-resilient communications.

Arizona – Tempe Resilience Hubs Microgrid Program:

• $20 million program adding solar, battery storage, and microgrid technology.

• Enables islanded operation during outages with backup power, HVAC, and essential services support.

• Pre-construction in late 2026.

Why Are Battery Projects Increasingly Attractive?

Drivers include:

• Renewable Integration: Batteries manage variability in solar and wind generation.

• Resilience: Support critical infrastructure during extreme weather or grid failures.

• Economic Efficiency: Peak shaving, load shifting, and reduced reliance on fossil fuels lower costs.

• Regulatory Support: Federal and state grants accelerate deployment in public-sector projects.

Batteries are no longer auxiliary technology; they are central to grid modernization and climate-resilient energy planning.

How Does This Trend Affect Government and Public-Sector Opportunities?

• Increased contracting for installation, engineering, and integration services.

• Opportunities to repurpose brownfield and decommissioned fossil-fuel sites.

• Funding programs from EPA, DOE, and state agencies support battery storage and microgrid deployment.

• Municipalities and utilities seek skilled contractors for design, permitting, cybersecurity integration, and grid interconnection.

What Is the Outlook for 2026 and Beyond?

• Continued growth in utility-scale and community-scale projects.

• Multi-gigawatt battery additions are expected annually, outpacing any prior record.

• Integration with renewable generation, microgrids, and climate resilience initiatives will become standard in planning.

• Public and private-sector partnerships will drive innovation, efficiency, and resilience at scale.

Conclusion

Battery energy storage is no longer supplementary; it has become essential for grid reliability, renewable integration, and climate resilience. Large-scale projects across California, Ohio, Florida, and Arizona demonstrate the strategic role of storage in both utility operations and public-sector initiatives. As installations accelerate, battery storage will define the next era of reliable, flexible, and sustainable energy infrastructure in 2026 and beyond.

Battery energy storage is overtaking diesel generators as the backbone of commercial and industrial backup power. Falling battery costs, hybrid inverter technologies, and regulatory pressures make battery-first systems more reliable, efficient, and sustainable. These systems handle daily grid disturbances, peak-demand events, and emergencies, reducing generator runtime while increasing operational resilience and cost-effectiveness.

How Have Regulations and Compliance Shaped Backup Power Planning?

In 2025, stricter rules for diesel generators changed the commercial energy landscape:

• Mandatory emission retrofits and maintenance logs increased compliance costs.

• Limited runtime hours reduced generator flexibility.

• Heightened enforcement and air-quality standards exposed operational risks for facilities using diesel generators frequently.

This regulatory pressure encouraged businesses to explore alternative, low-maintenance, and emissions-free energy solutions.

Why Are Diesel Generators Becoming Less Viable?

Diesel generators present several operational and logistical challenges:

• Noise and emissions create public scrutiny, particularly in hospitals, data centers, and mixed-use buildings.

• Fuel logistics are vulnerable to supply-chain disruptions and extreme weather events.

• Idle generators offer minimal daily value, operating only during rare outages.

These factors make generators a liability rather than a reliable, day-to-day resilience asset.

How Do Battery-First Architectures Improve Commercial Energy Resilience?

Battery-first systems integrate batteries, solar, grid power, and generators via modern hybrid inverters. Benefits include:

• Instant Response: Batteries handle short outages and grid disturbances immediately.

• Reduced Generator Stress: Fewer starts extend generator lifespan and reduce maintenance.

• Enhanced Operational Metrics: Improved frequency regulation, voltage support, and seamless transitions increase uptime and reliability.

This approach shifts the focus from theoretical power capacity to real-world operational resilience.

What Role Do Generators Play in Battery-First Systems?

Generators remain part of the energy ecosystem but with a redefined role:

• Run only during prolonged outages.

• Face less regulatory exposure and operational stress.

• Complement batteries by providing backup when extended energy support is needed.

Battery-first systems maximize efficiency, while generators provide contingency support.

How Does This Shift Impact Business Owners’ Decision-Making?

Owners now prioritize assets that are:

• Always available and silent.

• Emissions-free and low-maintenance.

• Independent of fuel deliveries and supply-chain constraints.

Batteries provide measurable value daily, including peak shaving, demand-charge reduction, and improved power quality, making them the preferred choice for modern facilities.

Redway Expert Views

“Battery-first energy storage is redefining commercial resilience. At Redway Battery, we see businesses benefiting from intelligent, always-on systems that reduce reliance on diesel generators while improving efficiency and sustainability. Hybrid inverter integration ensures batteries respond instantly to outages, extending generator life and minimizing operational risk. The future of reliable backup power is not more fuel—it’s smarter, cleaner energy storage.”

Conclusion

The evolution from generator-first to battery-first architectures reflects regulatory, economic, and operational realities. Battery energy storage delivers reliable, emissions-free, and intelligent power for daily and emergency use, while generators serve as secondary, contingency assets. Businesses adopting battery-first systems gain improved uptime, reduced operational risk, and long-term cost savings, making this shift essential for 2026 and beyond.

Frequently Asked Questions

Q1: Why are battery-first systems preferable to diesel generators?
They provide instant response, continuous value, lower emissions, and independence from fuel supply constraints.

Q2: Can generators still be used in battery-first systems?
Yes, they serve as secondary backup during extended outages while running less frequently.

Q3: How do hybrid inverters enhance energy storage systems?
They integrate batteries, solar, grid power, and generators, enabling seamless transitions and improved operational control.

Q4: What operational benefits do batteries offer daily?
Peak shaving, demand charge reduction, and improved voltage/frequency regulation enhance facility efficiency and resilience.

Q5: How does regulatory compliance impact generator use?
Stricter emissions rules, retrofits, and runtime limitations increase costs and risks, making batteries more attractive for commercial use.

Solid-state batteries are transforming defence platforms by offering unmatched energy density, safety, and longevity. ESOX Group is applying this technology to uncrewed aerial and ground vehicles, enabling higher endurance, lighter packs, and extreme temperature resilience. These batteries eliminate flammable electrolytes, reduce maintenance, and support modular, mission-specific power integration, strengthening operational readiness and strategic supply-chain independence.

How Do Solid-State Batteries Enhance Defence Platforms?

Solid-state batteries use solid electrolytes instead of flammable liquids, eliminating thermal runaway and metallic dendrite risks. With an energy density of 400 Wh/kg, these batteries allow lighter, more compact packs that improve manoeuvrability and range for drones and ground vehicles. Design life reaches up to 100,000 cycles, minimizing replacement needs and lifecycle costs while maintaining performance in extreme environments from –30°C to over 100°C.

What Features Make Solid-State Batteries Ideal for Military Use?

Key military advantages include:

• Enhanced Safety: No flammable electrolytes and reduced risk of thermal runaway.

• Extreme Temperature Tolerance: Over 99% capacity retention in cold and hot conditions.

• Long Lifecycle: Up to 100,000 charge cycles with minimal degradation.

• Rapid Charging: High charge rates without conventional lithium-ion limitations.

• Flexible Form Factor: Customizable sizes, voltages, and geometries for mission-specific integration.

These features enable engineers to optimize battery placement, vehicle design, and payload management without being constrained by legacy battery formats.

Which Defence Platforms Are Currently Integrating Solid-State Batteries?

ESOX Group has developed two practical integration platforms:

These platforms showcase real-world applications, moving the technology from lab validation to operational capability.

How Do Solid-State Batteries Strengthen Strategic Defence Capabilities?

Batteries have become central to modern defence, particularly as NATO and allied nations scale uncrewed and autonomous systems. Solid-state technology reduces dependency on foreign supply chains dominated by China, ensuring more resilient, geopolitically safe sourcing. By using abundant, non-critical materials, European manufacturers can produce cost-effective batteries aligned with strategic industrial policies.

What Advantages Does a “Designed in Europe, Built in Europe” Approach Offer?

Producing batteries locally supports supply-chain security and aligns with NATO-aligned industrial strategies. ESOX’s approach ensures:

• Geopolitically safe sourcing of materials.

• Reduced operational risk from supply-chain disruption.

• Integration with allied defence systems without dependency on external suppliers.

• Lower production costs compared with conventional lithium-ion technology.

Redway Expert Views

In defence applications, energy storage performance is mission-critical. Solid-state batteries provide unprecedented reliability, safety, and modularity for uncrewed systems. At Redway Battery, we recognize the importance of integrating these advanced chemistries into platforms designed for endurance and operational resilience. By leveraging solid-state technology, defence manufacturers can achieve lighter, safer, and longer-lasting power solutions while maintaining supply-chain security.”

How Are Solid-State Batteries Part of a Broader Defence Technology Suite?

Beyond energy storage, ESOX integrates solid-state batteries with:

• High-torque, low-signature electric propulsion.

• No-code software platforms for rapid control system development.

• Digital Twin 2.0 simulation for synchronized virtual and hardware testing.

This holistic approach shortens development cycles, reduces deployment risk, and allows platforms to be designed around mission requirements rather than fixed technology constraints.

Conclusion

Solid-state battery technology is poised to redefine defence capabilities by combining high energy density, extreme safety, long lifespan, and design flexibility. Platforms like ESOX’s X1 drone and X2 ground vehicle demonstrate how this technology translates into operational advantages, including enhanced endurance, survivability, and strategic supply-chain independence. For defence manufacturers, adopting solid-state batteries enables safer, more resilient, and cost-effective systems.

Frequently Asked Questions

Q1: Why are solid-state batteries preferred for military drones?
They provide lighter packs, longer endurance, and extreme temperature tolerance, crucial for mission success.

Q2: Can solid-state batteries be rapidly charged?
Yes, their chemistry supports faster charging than conventional lithium-ion systems without performance loss.

Q3: How do solid-state batteries improve supply-chain security?
They use abundant, geopolitically safe materials, reducing reliance on foreign suppliers and enhancing strategic resilience.

Q4: Are these batteries compatible with existing military platforms?
Yes, their customizable sizes, voltages, and geometries allow flexible integration into both air and ground systems.

Q5: What operational benefits do solid-state batteries offer?
Increased survivability, reduced maintenance, extended lifecycle, and improved payload optimization for uncrewed systems.