What question did this study set out to answer?

This research aims to optimize Ni-MOF-74 using argon plasma treatment to enhance ammonia synthesis efficiency.

June 4, 2026

From Plasma Modification to Plasma Catalysis: Discharge Time‐Controlled Tuning of Ni‐MOF‐74 for Enhanced Ammonia Synthesis

Key Points

This research aims to optimize Ni-MOF-74 using argon plasma treatment to enhance ammonia synthesis efficiency.
Employs argon plasma technology for surface modification of Ni-MOF-74.
Systematically investigates varying treatment durations on material properties and catalytic performance.
Uses density functional theory simulations to explore the mechanism of defect formation.
Ni-MOF-74 treated for 120 seconds achieved an ammonia synthesis rate of 10.77 mmol·g−1·h−1.
Nitrogen conversion rate reached 0.4% with a notable energy yield of 1.54 g·kWh−1.
Catalytic performance improved by 1.9 times compared to the untreated sample.

Abstract

ABSTRACT This study employed argon plasma technology for the surface modification of Ni‐MOF‐74, systematically investigating the influence of different treatment durations on the material's structure and catalytic performance. It was found that Ni‐MOF‐74 (Ar 120 s) exhibited an outstanding synergistic effect in the plasma‐catalytic synthesis of ammonia. The ammonia synthesis rate increased to 10.77 mmol·g −1 ·h −1 , with a nitrogen conversion rate of 0.4% and an energy yield of 1.54 g·kWh −1 , representing a 1.9 times improvement compared to the pristine sample. Density functional theory (DFT) simulations revealed the mechanism of plasma‐induced defect formation at the electronic structure level, clarifying the structure−activity relationship between material modification and catalytic performance.

From Plasma Modification to Plasma Catalysis: Discharge Time‐Controlled Tuning of Ni‐MOF‐74 for Enhanced Ammonia Synthesis

Key Points

Abstract

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