China Water Battery 120K Cycles Breakthrough | SUSTech Research

🔋 China's Aqueous Battery Revolution

Chinese researchers have unveiled a groundbreaking water-based battery that achieves over 120,000 charging cycles with minimal capacity loss, potentially outlasting traditional lithium-ion batteries by decades. This innovation, detailed in a recent Nature Communications publication, leverages a neutral pH electrolyte reminiscent of tofu brine to deliver exceptional stability, safety, and environmental compatibility. 83 61 Unlike conventional lithium-ion systems, which typically endure 1,000 to 3,000 cycles before significant degradation, this aqueous design promises a lifespan of 20 to 30 years under daily use, transforming prospects for grid-scale energy storage and renewable integration.

The development stems from collaborative efforts across top Chinese and Hong Kong institutions, underscoring China's rising dominance in advanced materials science and energy research. This achievement not only addresses key limitations in battery technology but also aligns with national priorities for sustainable energy solutions amid the global push for carbon neutrality.

Research Team and Leading Institutions

The study, titled "An aqueous battery using an electrolyte with a pH of 7 and suitable for direct environmental discard," was led by Hui Chen from the Department of Materials Science and Engineering at City University of Hong Kong (CityUHK), with contributions from Shuo Feng, Yutong Wang, and prominent battery expert Chunyi Zhi, also at CityUHK. 83 Key collaborators hail from Yan’an University in Shaanxi Province, Southern University of Science and Technology (SUSTech) in Shenzhen, and Songshan Lake Materials Laboratory in Dongguan.

SUSTech, a young but elite research university founded in 2012, exemplifies China's drive to foster innovation hubs, ranking highly in young university lists and excelling in materials engineering. Yan’an University contributes regional expertise in chemical engineering, while CityUHK's longstanding focus on energy storage—evident in projects like self-healing aqueous batteries—provides cutting-edge facilities. 62 This multi-institutional partnership highlights the strength of China's higher education ecosystem in tackling grand challenges like sustainable energy.

For aspiring researchers, opportunities abound at these institutions. Check out research jobs in materials science or explore faculty positions via higher ed faculty jobs.

Technical Breakdown: From Tofu Brine to Battery Power

The core innovation lies in the electrolyte: a neutral pH 7 solution of magnesium chloride (MgCl₂) or calcium chloride (CaCl₂), akin to the mineral-rich brine byproduct from tofu production. Traditional aqueous batteries suffer from acidic or alkaline electrolytes that trigger hydrogen evolution or corrosion, limiting lifespan. Here, the neutral environment—comparable to seawater—prevents these side reactions, enabling stable ion transport. 83

The negative electrode employs covalent organic polymers (COPs), specifically Hexaketone-tetraaminodibenzo-p-dioxin (HK-TADBD), synthesized via Schiff-base condensation. These polymers feature electron-donating linkers for fast divalent ion (Mg²⁺/Ca²⁺) intercalation at low potentials. The positive electrode pairs with compatible materials for a full cell operating at 2.2 volts.

• Step 1: Electrolyte preparation: Dissolve MgCl₂ or CaCl₂ in water to pH 7, mimicking tofu brine's composition for biocompatibility.
• Step 2: Electrode fabrication: Polymerize organic monomers into COP frameworks for reversible ion storage.
• Step 3: Assembly: Stack electrodes with separator in neutral electrolyte, yielding high-rate capability (20 A/g).
• Step 4: Cycling: Ions shuttle without degradation, achieving ultralong life.

This process is cost-effective, using abundant materials, and scalable for industrial production.

Impressive Performance Metrics

Lab prototypes deliver specific capacities up to 112.8 mAh/g for the negative electrode and 48.3 Wh/kg for the full cell (based on total active mass including electrolyte). At high rates of 20 A/g, it retains stability over 120,000 cycles with negligible fade—equivalent to decades of daily charging. 83

These figures position it ideally for stationary storage, where longevity trumps density.

Photo by Hongwei FAN on Unsplash

Safety and Environmental Edge Over Lithium-Ion

Lithium-ion batteries' organic electrolytes are flammable, prone to thermal runaway (fires in EVs, grids), and contain cobalt/lithium with mining impacts. This water battery eliminates these: non-flammable, no toxic metals, and electrolytes compliant with disposal standards (GB 18599-2020, ISO 14001). Direct environmental discard is feasible, reducing e-waste burdens. 60

• Zero fire risk: Neutral aqueous medium suppresses dendrites.
• Biodegradable: Tofu-like brine harmless to ecosystems.
• Low cost: Abundant salts vs rare earths.

In China, where battery production dominates globally, this supports greener manufacturing at unis like SUSTech.

Applications: Powering China's Renewable Boom

China leads in solar/wind capacity, but intermittency demands robust storage. This battery suits grid-scale buffering, peak shaving, and microgrids in remote areas. Potential in data centers, EVs for fleets (longevity offsets density), and military backups. Researchers envision pairing with photovoltaics for off-grid higher ed campuses.Read the full Nature paper

For engineers, career advice on battery R&D is essential.

Challenges on the Road to Commercialization

While promising, energy density (48 Wh/kg) lags Li-ion, limiting portable uses. Scalability requires pilot plants; cost modeling and standardization next. SUSTech's innovation ecosystem positions it well for tech transfer.

Broader Impacts on Higher Education and Research

This work exemplifies interdisciplinary collaboration in China's unis, blending chemistry, materials engineering, and environmental science. SUSTech's rise as a research powerhouse attracts global talent; Yan’an University bridges regional innovation.

Stakeholders praise the eco-focus amid China's dual-carbon goals. Experts note it accelerates aqueous battery shift, inspiring PhD programs in energy storage.

Photo by Atul Vinayak on Unsplash

Career Opportunities in Battery Innovation

Battery research booms in China. Postdocs at SUSTech or CityUHK advance sustainable tech. Explore postdoc jobs, research assistant roles, or faculty at Chinese universities. Rate your professors and build networks.

Future Outlook: A Decade to Deployment?

Researchers target industry pilots in 5-7 years, leveraging China's supply chains. Global implications: safer grids, reduced Li dependence. Unis like SUSTech lead patents, fostering startups.

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