Heteroatom‑coordinated Fe–N4 catalysts for enhanced oxygen reduction in alkaline seawater zinc‑air batteries

As maritime electrification and blue-energy harvesting accelerate, conventional Pt/C cathodes collapse in natural seawater because chloride ions poison active sites and shift the oxygen-reduction pathway from the desired 4 e⁻ route to the parasitic 2 e⁻ peroxide route. Now, researchers from Central South University and Xi’an Jiaotong-Liverpool University, led by Professor Jun Wu and Professor Danlei Li, have unveiled a universal oxidative-polymerization route that axially clamps Fe–N₄ single-atom sites with heteroatoms (Cl or S) to create square-pyramidal “Cl–Fe–N ₄ ” catalysts that repel Cl⁻ while doubling reaction kinetics. The work is published in Nano-Micro Letters .

Why Heteroatom Axial Coordination Matters
• Chloride Shield : Axial Cl pulls electron density toward itself, generating a negatively charged Fe center that electro-statically rejects Cl⁻ adsorption, keeping 96.7 % current retention after 12 h in pH-13 synthetic seawater.
• Intrinsic Boost : The Cl–Fe bond shortens the Fe–N bond length to 1.91 Å, down-shifts the d-band center to –2.94 eV and lowers the *OH-to-H ₂ O rate-limiting step from 0.86 eV to 0.63 eV, delivering a record 5.8 mA cm ^-2 limiting current density that outperforms 40 wt % Pt/C (3.0 mA cm ^-2 ).
• Seawater Compatibility : The five-coordinated geometry maintains a strict 4 e⁻ pathway (n = 4.02) even in 0.5 M KCl, whereas undoped Fe–N₄ collapses to 2.24.

Innovative Design and Features
• One-Pot Synthesis : 1,5-diaminonaphthalene oxidative polymerization at 80 °C followed by 950 °C Ar pyrolysis and acid leaching yields 708 m ² g ^-1 microporous carbon with atomically dispersed Fe and 4.73 % N content.
• Spectroscopic Proof : HAADF-STEM, XANES and EXAFS confirm the absence of Fe clusters; only a single Fe–Cl shell at 2.17 Å is detected, matching square-pyramidal Cl–Fe–N ₄ .
• Device Validation : When coated on nickel-foam air-cathodes (1 mg cm ^-2 ), the Cl–Fe–N₄ seawater zinc-air battery delivers 187.7 mW cm ^-2 peak power at 245.1 mA cm ^-2 and sustains 200 h of deep discharge–charge cycles at 10 mA cm ^-2 with only 7 mV half-wave-potential decay.

Applications and Future Outlook
• Maritime Power Packs : Coupled with printable Zn anodes, the catalyst enables pouch cells that operate directly in ocean water, promising buoy-based sensors and unmanned underwater vehicles.
• Off-Grid Desalination : High current density at low overpotential allows SZAB-driven membrane pumps that consume 30 % less energy than conventional reverse-osmosis systems.
• Scalable Manufacturing : The precursor ink is water/ethanol-based and the maximum processing temperature is <1000 °C, making roll-to-roll production compatible with existing carbon-fiber lines.
• Next-Gen Tuning : The team is exploring F and Br axial ligands and dual-metal (Fe/Co) centers to further widen the operating salinity window to 10 wt % NaCl.

This comprehensive study provides a materials-by-design playbook for turning the most abundant anion in the ocean—chloride—from a poison into a performance descriptor, paving the way for truly seawater-robust energy storage and conversion devices.

Nano-Micro Letters

10.1007/s40820-025-01943-6

News article

Heteroatom‑Coordinated Fe–N4 Catalysts for Enhanced Oxygen Reduction in Alkaline Seawater Zinc‑Air Batteries

3-Jan-2026