Abstract
Electrochemical remediation of ammonia-containing wastewater at low cell voltage is an energy-effective technology which can simultaneously recover energy via hydrogen evolution reaction. One of the main challenges is to identify a robust, highly active and inexpensive anode for ammonia electrooxidation. Here we present an alternative anode, prepared by electrochemical co-deposition of Ni and Cu onto carbon paper. This NiCu bimetallic catalyst is characterised by scanning electron microscope, scanning transmission electron microscope, X-ray diffraction, x-ray photoelelectron spectroscopy, cyclic voltammetry, linear sweep voltammetry and chronoamperometry techniques. The stability and activity of NiCu bimetallic catalyst are largely improved in comparison with Ni or Cu catalyst. Moreover this noble-metal-free NiCu catalyst even performs better than Pt/C catalyst, as NiCu is not poisoned by ammonia. An ammonia electrolysis cell is fabricated with NiCu/carbon paper as anode for ammonia electrolysis. The influences of pH value, applied cell voltages and initial ammonia concentration on cell current density, ammonia removal and energy efficiency are tested. An ammonia removal efficiency of ∼80% and coulombic efficiency up to ∼92% have been achieved. Ni-Cu bimetal on carbon paper is a stable non-noble anode for efficient electrooxidation of ammonia.
Highlights
The discharge of ammonia-containing wastewater into natural environment can damage ecological balance, which is known as eutrophication [1,2]
In this work we present a method of electrodeposition of NiCu bimetal on carbon paper for ammonia electrooxidation
When Ni and Cu were co-electrodeposited on carbon paper (NiCu/CP), the Cu2O(111) peak became very weak and Cu(111) and Cu(200) peaks were newly observed at 2Â angles of 43◦ and 50.3◦, respectively
Summary
The discharge of ammonia-containing wastewater into natural environment can damage ecological balance, which is known as eutrophication [1,2]. Only a small value of external energy (0.06 V) is required to crack ammonia to nitrogen and hydrogen [15] It is much lower than the energy (1.23 V) required by water electrolysis: CuSO4·5H2O and 0.5 M SDS was used as deposition electrolyte. Bimetallic NiCu catalyst is reported to have improved activity for methanol electrooxidation and water electrolysis [25,26,27,28], as well as enhanced stability [29]. NiCu coated carbon paper electrode is further used as noble-metal-free anode to fabricate ammonia electrolysis cell (AEC). This AEC can work under low cell voltage to achieve an energy-effective degradation, which is especially capable of ammonia-rich wastewater
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