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Lignin-Directed Construction of Vertical Ru/RuO <sub>2</sub> Electron–Bridge Interfaces for Low-Input Self-Powered Hydrazine-Water Splitting

Jianglin Liu, Jinhui Zhang, Liheng Chen, Yanlin Qin, Xuliang Lin, Xueqing Qiu

2025Journal of the American Chemical Society38 citationsDOI

Abstract

High Resolution Image Download MS PowerPoint Slide Hydrazine oxidation reaction (HzOR) has emerged as a promising anodic alternative to the oxygen evolution reaction (OER) for efficient hydrogen production. Nevertheless, two-electrode electrolyzers demand substantial cell voltages and uninterrupted external power, curbing scalable implementation. Herein, hydrothermally activated lignin chelates with Ru 3+ to direct the in situ formation of Ru/RuO 2 heterojunctions that, upon pyrolysis, are embedded within a hierarchical lignin-derived carbon (HLC) matrix to yield the Ru/RuO 2 @HLC catalyst. Combined spectroscopy and DFT calculation uncover a dynamic dual-center (DDC) at the interface: a Ru 4+ –O–Ru 0 electron bridge injects charge into RuO 2, while adjacent Ru undergoes reversible partial oxidation (Ru 0 ↔ Ru 3+ ) under bias. This DDC slightly elongates Ru–O and compresses Ru–Ru, enriches lattice oxygen, accelerates interfacial charge transfer, lowers the free-energy barrier of the rate-limiting *2NH → *2N step to 1.31 eV, and suppresses high-valence Ru dissolution. In 1.0 M KOH electrolyte, the as-prepared Ru/RuO 2 @HLC catalyst achieves a hydrogen evolution reaction (HER) current density of 50 mA cm –2 at an exceptionally low overpotential of 12 mV and surpasses commercial Pt/C. Replacing OER with HzOR significantly reduces the cell voltage to only 0.14 V at 100 mA cm –2 . A paired direct hydrazine fuel cell and an integrated overall hydrazine splitting deliver 2.32 mmol h –1 of hydrogen at approximately 100% Faradaic efficiency, representing one of the highest hydrogen production rates reported to date for self-powered hydrazine systems. This work provides a scalable platform for waste-to-hydrogen conversion and highlights the potential of renewable biomass ligands for constructing high-performance interfacial electrocatalysts.

Topics & Concepts

OverpotentialChemistryOxygen evolutionFaraday efficiencyHydrogen productionCatalysisHydrogenHydrazine (antidepressant)AnodeWater splittingChemical engineeringInorganic chemistryHeterojunctionElectrochemistryNanotechnologyPartial oxidationElectrolysis of waterHydrogen fuelSteam reformingYield (engineering)Reversible hydrogen electrodeVoltageElectrocatalysts for Energy ConversionAdvanced battery technologies researchAmmonia Synthesis and Nitrogen Reduction