用于高效光催化 NO 氧化的 ZnCr-LDH/NH-UIO66 异质结中的双位点朗缪尔-欣谢尔伍德机制
Dual-site Langmuir-Hinshelwood mechanism in ZnCr-LDH/NH-UIO66 heterojunction for efficient photocatalytic NO oxidation.
作者信息
Guo Jing, Ma Haotong, Shang Huan, Wang Wenchao, Yang Ruiyi, Wang Shuo, Miao Yingchun, Phillips David Lee, Li Guisheng, Xiao Shuning
机构信息
School of Materials and Chemistry, University of Shanghai for Science and Technology, Shanghai 200093, China.
Department of Chemistry, The University of Hong Kong, Hong Kong.
出版信息
J Hazard Mater. 2025 Jul 15;492:138060. doi: 10.1016/j.jhazmat.2025.138060. Epub 2025 Mar 28.
In this study, we developed a ZnCr-LDH/NH-UIO66 heterojunction to enhance photocatalytic NO oxidation through a dual-site Langmuir-Hinshelwood (L-H) mechanism. Nitrogen oxides (NOₓ), including NO, are hazardous environmental contaminants linked to severe air pollution issues such as haze, acid rain, and photochemical smog. The composite catalyst addresses these challenges by synergistically activating NO and O under environmentally relevant conditions, including simulated solar light, ambient temperature, and NO concentrations of 1000 ppb typical of polluted urban areas. The MOF component (NH-UIO66) selectively adsorbs NO, while the LDH component (ZnCr-LDH) efficiently activates O to generate reactive oxygen species (ROS). The built-in electric field (BIEF) optimizes charge separation, enabling 71.1 % NO removal efficiency with 97.8 % nitrate selectivity, effectively suppressing toxic NO byproduct formation. This work provides a sustainable strategy for mitigating hazardous NO emissions in air pollution control, bridging material design with environmental remediation.
在本研究中,我们开发了一种ZnCr-LDH/NH-UIO66异质结,以通过双位点朗缪尔-欣谢尔伍德(L-H)机制增强光催化NO氧化。氮氧化物(NOₓ),包括NO,是与雾霾、酸雨和光化学烟雾等严重空气污染问题相关的有害环境污染物。该复合催化剂通过在环境相关条件下协同活化NO和O来应对这些挑战,这些条件包括模拟太阳光、环境温度以及污染城市地区典型的1000 ppb的NO浓度。MOF组分(NH-UIO66)选择性吸附NO,而LDH组分(ZnCr-LDH)有效活化O以产生活性氧物种(ROS)。内置电场(BIEF)优化了电荷分离,实现了71.1%的NO去除效率和97.8%的硝酸盐选择性,有效抑制了有毒NO副产物的形成。这项工作为减轻空气污染控制中的有害NO排放提供了一种可持续策略,将材料设计与环境修复联系起来。
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