Current Issue Volume 36 Issue 4
The image depicts a scenario where buildings, paved surfaces, and vehicles spontaneously purify air pollutants in an "environmentally catalytic city." By applying catalytic materials, urban surfaces can autonomously catalyze and purify low-concentration gaseous pollutants under natural light and heat conditions. This includes oxidizing and removing nitrogen oxides, volatile organic compounds, and decomposing ozone. Developing an "environmentally catalytic city" is crucial for low-carbon control of complex air pollution, significantly enhancing the city's self-cleaning capability and continuously improving environmental quality.
The image depicts a scenario where buildings, paved surfaces, and vehicles spontaneously purify air pollutants in an "environmentally catalytic city." By applying catalytic materials, urban surfaces can autonomously catalyze and purify low-concentration gaseous pollutants under natural light and heat conditions. This includes oxidizing and removing nitrogen oxides, volatile organic compounds, and decomposing ozone. Developing an "environmentally catalytic city" is crucial for low-carbon control of complex air pollution, significantly enhancing the city's self-cleaning capability and continuously improving environmental quality.
