A promising way to address environmental problems caused by plastic waste is through its upcycling into renewable energy and resources.With annual production reaching millions of tons,one of the most widely single-use...A promising way to address environmental problems caused by plastic waste is through its upcycling into renewable energy and resources.With annual production reaching millions of tons,one of the most widely single-use daily plastics,polyethylene terephthalate(PET),has recently been investigated in terms of chemical recycling to reduce its environmental impact and generate renewable fuels.This study introduces an innovative electrochemical method for the specific conversion of PET hydrolysate into highvalue compounds utilizing CoCuO_(x)@MXene/NF catalyst.Our findings revealed that the electrocatalyst was capable of facilitating the conversion of water into hydrogen(H_(2)),while simultaneously oxidizing ethylene glycol(EG),obtained from PET plastic waste hydrolysis,into formate with a high selectivity and lower initial potential compared to water oxidation.Notably,the exceptional performance was attributed to the synergistic interfacial electronic coupling effect between CoCuO_(x)and MXene,which results in a low overpotential(1.24 V@10 mA cm^(-2))and a high yield of formate product(87.6%).In addition,the electrolyzer could be operated using solar energy panel for upcycling of PET to formic acid and hydrogen fuels by using CoCuO_(x)@MXene catalyst.展开更多
Two series of thieno[2,3-d]pyrimidine derivatives were designed and synthesized, in which bioactive α-aminophosphonate subunits were introduced at the N3 position through an N-N bond connection. The in vitro cytotoxi...Two series of thieno[2,3-d]pyrimidine derivatives were designed and synthesized, in which bioactive α-aminophosphonate subunits were introduced at the N3 position through an N-N bond connection. The in vitro cytotoxic activity of the novel compounds was tested against human esophageal carcinoma cells (EC109), human hepatocarcinoma cells (HepG2), human gastric carcinoma cells (MGC-803), respectively, by the MTT method. The evaluation results revealed that compounds fimb, 6mf, 6mg, 6rid and 6nh exerted the most potent inhibition against HepG2, MGC-803 and EC109 cells, respectively. In particular, compound 6rag presented excellent inhibitory effect against HepG2 (91.2%) and MGC-803 (94.4%) cells.展开更多
基金The financial assistance provided by the Centre National de la Recherche Scientifique(CNRS),the University of Lille,the Hautsde-France region,and the CPER“Wavetech”are acknowledgedthe Chinese government for the China Scholarship Council(CSC)fellowship。
文摘A promising way to address environmental problems caused by plastic waste is through its upcycling into renewable energy and resources.With annual production reaching millions of tons,one of the most widely single-use daily plastics,polyethylene terephthalate(PET),has recently been investigated in terms of chemical recycling to reduce its environmental impact and generate renewable fuels.This study introduces an innovative electrochemical method for the specific conversion of PET hydrolysate into highvalue compounds utilizing CoCuO_(x)@MXene/NF catalyst.Our findings revealed that the electrocatalyst was capable of facilitating the conversion of water into hydrogen(H_(2)),while simultaneously oxidizing ethylene glycol(EG),obtained from PET plastic waste hydrolysis,into formate with a high selectivity and lower initial potential compared to water oxidation.Notably,the exceptional performance was attributed to the synergistic interfacial electronic coupling effect between CoCuO_(x)and MXene,which results in a low overpotential(1.24 V@10 mA cm^(-2))and a high yield of formate product(87.6%).In addition,the electrolyzer could be operated using solar energy panel for upcycling of PET to formic acid and hydrogen fuels by using CoCuO_(x)@MXene catalyst.
基金supported by the National Natural Sciences Foundations of China (Nos.21171149,21105091)
文摘Two series of thieno[2,3-d]pyrimidine derivatives were designed and synthesized, in which bioactive α-aminophosphonate subunits were introduced at the N3 position through an N-N bond connection. The in vitro cytotoxic activity of the novel compounds was tested against human esophageal carcinoma cells (EC109), human hepatocarcinoma cells (HepG2), human gastric carcinoma cells (MGC-803), respectively, by the MTT method. The evaluation results revealed that compounds fimb, 6mf, 6mg, 6rid and 6nh exerted the most potent inhibition against HepG2, MGC-803 and EC109 cells, respectively. In particular, compound 6rag presented excellent inhibitory effect against HepG2 (91.2%) and MGC-803 (94.4%) cells.
