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�Ӱ���Ƶ researcher advances zinc-sulfur battery technology

Rechargeable lithium-ion batteries power everything from electric vehicles to wearable devices. But new research from �Ӱ���Ƶ suggests that a more sustainable and cost-effective alternative may lie in zinc-based batteries.

In a study published recently in , researchers announced a significant step toward creating high-performance, low-cost zinc-sulfur batteries.

“This research marks a major step forward in the development of safer and more sustainable energy storage solutions,” said , a principal investigator and assistant professor of mechanical and aerospace engineering at Case School of Engineering. “Aqueous zinc-sulfur batteries offer the potential to power a wide range of applications—from renewable energy systems to portable electronics—with reduced environmental impact and reliance on scarce materials.”

Cheaper, more abundant raw materials

Lithium-ion batteries, though widely used, are expensive, rely on relatively rare materials and are complex to manufacture. In contrast, zinc-sulfur batteries use more abundant and inexpensive materials and have fewer environmental and safety concerns.

However, such as zinc-anode corrosion, low conductivity and dendrite growth have historically hindered their commercial viability.

Cao’s team overcame these obstacles by introducing two key additives: propylene glycol methyl ether and zinc-iodide. This technology delivered several crucial improvements: enhanced energy capacity by 20%, improved conductivity and stability and inhibited the growth of zinc dendrites.

If the dendrites connect the positive and negative sides of the battery, it can short out and cause a fire—another major problem with lithium-ion batteries.

“These additives not only enhance battery efficiency, but also address long-standing safety concerns by mitigating dendrite formation,” said , professor at Donghua University in Shanghai and co-senior author. “The result is a compact, higher-density battery that can recharge more times without significant degradation.”

Smaller, more efficient batteries

The implications of this breakthrough extend beyond affordability and safety. Zinc-sulfur batteries have a higher energy density than lithium-ion counterparts, enabling smaller, longer-lasting designs. This could be transformative for renewable energy storage and devices that demand reliability and efficiency.

Cao’s primary interest in developing better batteries is for novel soft robotics and advanced sensing systems, both of which rely on high-capacity, long-lived batteries. For example, he’s developing , whose endurance relies on durable, lightweight batteries that can power long missions without failure—the robot can’t run out mid-mission or will never come back. Cao, who directs the at CWRU, is also developing new technologies for space exploration and farming, as well as for removing ubiquitous and dangerous space debris.

The research was also conducted with researchers from Fudan University in Shanghai and The Hong Kong University of Science and Technology.

For more information, contact Diana Steele, diana.steele@case.edu.