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Volume 40 Issue 5
Jul.  2022
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Article Contents
SUN Su-yun, LI Bao-lei, KONG De-yong, HOU Ya-nan, MA Jin-feng, GUO Jian-bo, SONG Yuan-yuan. ADSORPTION AND TRANSFORMATION OF CHLOROPYRIDINE: RESEARCH ADVANCES AND CHALLENGES[J]. ENVIRONMENTAL ENGINEERING , 2022, 40(5): 227-236. doi: 10.13205/j.hjgc.202205032
Citation: SUN Su-yun, LI Bao-lei, KONG De-yong, HOU Ya-nan, MA Jin-feng, GUO Jian-bo, SONG Yuan-yuan. ADSORPTION AND TRANSFORMATION OF CHLOROPYRIDINE: RESEARCH ADVANCES AND CHALLENGES[J]. ENVIRONMENTAL ENGINEERING , 2022, 40(5): 227-236. doi: 10.13205/j.hjgc.202205032

ADSORPTION AND TRANSFORMATION OF CHLOROPYRIDINE: RESEARCH ADVANCES AND CHALLENGES

doi: 10.13205/j.hjgc.202205032
  • Received Date: 2021-07-19
    Available Online: 2022-07-02
  • The mass production of chloropyridine herbicides and their wide application in agricultural production and daily life causes them to be continuously detected in wastewater, drinking water, and other environments, and possesses potential hazards to the ecological environment and human health. How to effectively remove chloropyridine contaminants becomes a focus in the field of water pollution control. In terms of compound structure, the breaking of the C-Cl bond is critical to the degradation of chloropyridine compounds. This work provides an overview of research advances in the removal of chloropyridine contaminants and challenges. Related strategies including adsorption, advanced oxidation methods, catalytic hydrogenation and coupling technologies, etc., have demonstrated an excellent pollutant detoxification effect. The mechanisms, process parameters, and major challenges of pollutants removal are discussed in detail. The adsorption method faces problems such as difficulty in degrading pollutants, developing new adsorbent materials, and adsorbent regeneration. Advanced oxidation technology has a high pollutant mineralization rate, but its disadvantages are low oxidation efficiency and high operating cost. The catalytic hydrogenation degraded pollutants directionally, but the degradation is still incomplete. Biological treatment technology is economical and effective, but the removal rate of pollutants still needs to be improved. The studies indicate that due to the refractory characteristics of chloropyridine contaminants, it is efficient to remove the pollutants with independent treatment technology. The combination of multiple treatment methods is a feasible strategy for the efficient removal of pollutants. Researches on the transformation technologies and mechanisms of chloropyridine in the environment have important theoretical and practical guiding value for the efficient detoxification and degradation of risk pollutants.
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