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Simultaneous capture of trace benzene and SO 2 in a robust Ni(II)-pyrazolate framework.

Guang-Rui SiXiang-Jing KongTao HeZhengqing ZhangJian-Rong Li
Published in: Nature communications (2024)
Benzene and SO 2 , coexisting as hazardous air pollutants in some cases, such as in coke oven emissions, have led to detrimental health and environmental effects. Physisorbents offer promise in capturing benzene and SO 2 , while their performance compromises at low concentration. Particularly, the simultaneous capture of trace benzene and SO 2 under humid conditions is attractive but challenging. Here, we address this issue by constructing a robust pyrazolate metal-organic framework (MOF) sorbent featuring rich accessible Ni(II) sites with low affinity to water and good stability. This material achieves a high benzene uptake of 5.08 mmol g -1 at 10 Pa, surpassing previous benchmarks. More importantly, it exhibits an adsorption capacity of ~0.51 mmol g -1 for 10 ppm benzene and ~1.21 mmol g -1 for 250 ppm SO 2 under 30% relative humidity. This work demonstrates that a pioneering MOF enables simultaneous capture of trace benzene and SO 2 , highlighting the potential of physisorbents for industrial effluent remediation, even in the presence of moisture.
Keyphrases
  • metal organic framework
  • heavy metals
  • healthcare
  • public health
  • wastewater treatment
  • deep learning
  • machine learning
  • big data
  • climate change
  • artificial intelligence
  • life cycle
  • municipal solid waste