二氧化钛
固氮
催化作用
电极
固定(群体遗传学)
等离子体
氮气
钛
材料科学
无机化学
化学
化学工程
复合材料
有机化学
冶金
生物化学
工程类
物理化学
物理
基因
量子力学
作者
Pradeep Lamichhane,Nima Pourali,Evgeny V. Rebrov,Volker Hessel
标识
DOI:10.1002/slct.202401076
摘要
Abstract This research explores the potential of electric field enforcement in dielectric barrier discharge using specially designed pyramid‐shaped μ‐electrodes for a plasma‐assisted nitrogen fixation process. The obtained results are compared under varying conditions, including the presence and absence of titanium dioxide ( ), different oxygen concentrations in the nitrogen‐feeding gas, and residence time. The results demonstrate that the μ‐electrodes lead to an enhancement of nitrogen oxidation, which is further intensified by . The introduction of 60–70 % oxygen with nitrogen achieves the highest level of production. The synergistic effect of plasma and the catalytic effect of increase the rate of production by 20 %, resulting in a 23 % increase in energy yield. The introduction of leads to a sharp increase in production even at lower oxygen concentrations. The crucial role played by ultraviolet light‐induced electron‐hole pairs in is highlighted to promote nitrogen oxidation. Nevertheless, it is crucial to emphasize that prolonged residence times may cause the photocatalytic effect to generate alternative byproducts rather than , consequence of excessive oxidation that could prove counterproductive. These findings emphasize the potential of plasma‐assisted nitrogen fixation technology in reducing energy costs and meeting the growing demand for sustainable nitrogen‐based fertilizers.
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