One of the main challenges in oil-water separation of traditional Chinese medicines(TCM)is to obtain essential oils from the aromatic water of TCM.In this study,silicon dioxide/polyvinylidene fluoride(SiO_(2)/PVDF)mem...One of the main challenges in oil-water separation of traditional Chinese medicines(TCM)is to obtain essential oils from the aromatic water of TCM.In this study,silicon dioxide/polyvinylidene fluoride(SiO_(2)/PVDF)membranes were prepared using nonsolvent induce phase separation.Then polydimethylsiloxane(PDMS)was coated to obtain PDMS/SiO_(2/)PVDF membranes.Separated essential oils and water from aromatic water in the gaseous state by vapor permeation membrane separation technology.The relationship between membrane structure and membrane separation effect was investigated.Response surface methodology was used to develop a quadratic model for the separation factor,membrane permeation separation index and membrane preparation process.The optimal process parameters for the membrane separation were 12.31%(mass)concentration of PVDF solution,9.6%(mass)of N,Ndimethylacetamide in the solidification bath,and 0.2 g hydrophobic nano-SiO_(2)incorporation,with a separation factor of 14.45,and a membrane flux of 1203.04 g·m^(-2)·h^(-1).Compared with the PDMS/PVDF membranes,the separation factor and membrane flux were increased by 68.59%and 3.46%,respectively.Compared with the SiO_(2)/PVDF membranes,the separation factor and membrane flux were increased by478%and 79.33%,respectively.Effectively mitigated the limitations of traditional polymer membrane material performance affected by the"trade-off"effect.Attenuated total internal reflection-Fourier transform infrared spectroscopy,contact angle,scanning electron microscopy and energy dispersive spectroscopy were used to characterize the PDMS/SiO_(2)/PVDF membranes,and gas chromatography was used to characterize the permeate.In addition,the contents of L-menthol,L-menthone,menthyl acetate and limonene in the permeate,conformed to the European Pharmacopoeia standards.This study provided an effective preparation strategy of a feasible hydrophobic powder polymer membrane for the separation of essential oils from gaseous peppermint aromatic water.展开更多
In this study,graphene oxide was covalently immobilized on silica-coated magnetite and then modified with 2-phenylethylamine to give a nanocomposite of type Fe3O4@SiO2@GO-PEA that can be applied to the magnetic solid-...In this study,graphene oxide was covalently immobilized on silica-coated magnetite and then modified with 2-phenylethylamine to give a nanocomposite of type Fe3O4@SiO2@GO-PEA that can be applied to the magnetic solid-phase extraction of polycyclic aromatic hydrocarbons(PAHs) from water samples.The resulting microspheres(Fe3O4@SiO2@GO-PEA) were characterized by Fourier transform-infrared spectroscopy(FT-IR),scanning electron microscopy(SEM),CHNS elemental analysis,and vibrating sample magnetometry(VSM) techniques.The adsorbent possesses the magnetic properties of Fe3O4 nanoparticles that allow them easily to be separated by an external magnetic field.They also have the high specific surface area of graphene oxide which improves adsorption capacity.Desorption conditions,extraction time,amount of adsorbent,salt concentration,and pH were investigated and optimized.Following desorption,the PAHs were quantified by gas chromatography with flame ionization detection(GC-FID).The limits of detection(at an S/N ratio of 3) were achieved from 0.005 to0.1 μg/L with regression coefficients(R2) higher than 0.9954.The relative standard deviations(RSDs) were below 5.8%(intraday) and 6.2%(inter-day),respectively.The method was successfully applied to the analysis of PAHs in environmental water samples where it showed recoveries in the range between 71.7%and 106.7%(with RSDs of 1.6%to 8.4%,for n = 3).The results indicated that the Fe3O4@SiO2@GO-PEA microspheres had a great promise to extraction of PAHs from different water samples.展开更多
Atmospheric fine particles (PM2.5) were collected in this study with middle volume samplers in Fuzhou, China, during both normal days and haze days in summer (September 2007) and winter (january 2008). The conce...Atmospheric fine particles (PM2.5) were collected in this study with middle volume samplers in Fuzhou, China, during both normal days and haze days in summer (September 2007) and winter (january 2008). The concentrations, distributions, and sources of polycyclic aromatic hydrocarbons (PAHs), organic carbon (OC), elemental carbon (EC), and water soluble inorganic ions (WSIls) were determinated. The results showed that the concentrations of PM2.s, PAHs, OC, EC, and WSIIs were in the orders of haze 〉 normal and winter〉 summer. The dominant PAHs of PM2.s in Fuzhou were Fluo, Pyr, Chr, BbF, BkF, BaP, BghiP, and IcdP, which represented about 80.0% of the total PAHs during different sampling periods. The BaPeq concentrations of ^-~PAHs were 0.78, 0.99, 1.22, and 2.43 ng/m3 in summer normal, summer haze, winter normal, and winter haze, respectively. Secondary pollutants (SO42 , NO3 , NH4*, and OC) were the major chemical compositions of PM2.5, accounting for 69.0%, 55.1%, 63.4%, and 64.9% of PM2.s mass in summer normal, summer haze, winter normal, and winter haze, respectively. Correspondingly, secondary organic carbon (SOC) in Fuzhou accounted for 20.1%, 48.6%, 24.5%, and 50.5% of OC. The average values of nitrogen oxidation ratio (NOR) and sulfur oxidation ratio (SOR) were higher in haze days (0.08 and 0.27) than in normal days (0.05 and 0.22). Higher OC/EC ratios were also found in haze days (5.0) than in normal days (3.3). Correlation analysis demonstrated that visibility had positive correlations with wind speed, and neg- ative correlations with relative humidity and major air pollutants. Overall, the enrichments of PM2.5, OC, EC, SO42 ,andNO3 promoted haze formation. Furthermore, the diagnostic ratios of IcdP/(IcdP + BghiP), lcdP/BghiP, OC/EC, and NO3 /SO42 indicated that vehicle exhaust and coal consumption were the main sources of pollutants in Fuzhou.展开更多
基金supported by the National Natural Science Foundation of China(22478007)the National Key Research and Development Program of China(2022YFB3805100)the Anhui Provincial Natural Science Foundation(2023AH050728)。
文摘One of the main challenges in oil-water separation of traditional Chinese medicines(TCM)is to obtain essential oils from the aromatic water of TCM.In this study,silicon dioxide/polyvinylidene fluoride(SiO_(2)/PVDF)membranes were prepared using nonsolvent induce phase separation.Then polydimethylsiloxane(PDMS)was coated to obtain PDMS/SiO_(2/)PVDF membranes.Separated essential oils and water from aromatic water in the gaseous state by vapor permeation membrane separation technology.The relationship between membrane structure and membrane separation effect was investigated.Response surface methodology was used to develop a quadratic model for the separation factor,membrane permeation separation index and membrane preparation process.The optimal process parameters for the membrane separation were 12.31%(mass)concentration of PVDF solution,9.6%(mass)of N,Ndimethylacetamide in the solidification bath,and 0.2 g hydrophobic nano-SiO_(2)incorporation,with a separation factor of 14.45,and a membrane flux of 1203.04 g·m^(-2)·h^(-1).Compared with the PDMS/PVDF membranes,the separation factor and membrane flux were increased by 68.59%and 3.46%,respectively.Compared with the SiO_(2)/PVDF membranes,the separation factor and membrane flux were increased by478%and 79.33%,respectively.Effectively mitigated the limitations of traditional polymer membrane material performance affected by the"trade-off"effect.Attenuated total internal reflection-Fourier transform infrared spectroscopy,contact angle,scanning electron microscopy and energy dispersive spectroscopy were used to characterize the PDMS/SiO_(2)/PVDF membranes,and gas chromatography was used to characterize the permeate.In addition,the contents of L-menthol,L-menthone,menthyl acetate and limonene in the permeate,conformed to the European Pharmacopoeia standards.This study provided an effective preparation strategy of a feasible hydrophobic powder polymer membrane for the separation of essential oils from gaseous peppermint aromatic water.
文摘In this study,graphene oxide was covalently immobilized on silica-coated magnetite and then modified with 2-phenylethylamine to give a nanocomposite of type Fe3O4@SiO2@GO-PEA that can be applied to the magnetic solid-phase extraction of polycyclic aromatic hydrocarbons(PAHs) from water samples.The resulting microspheres(Fe3O4@SiO2@GO-PEA) were characterized by Fourier transform-infrared spectroscopy(FT-IR),scanning electron microscopy(SEM),CHNS elemental analysis,and vibrating sample magnetometry(VSM) techniques.The adsorbent possesses the magnetic properties of Fe3O4 nanoparticles that allow them easily to be separated by an external magnetic field.They also have the high specific surface area of graphene oxide which improves adsorption capacity.Desorption conditions,extraction time,amount of adsorbent,salt concentration,and pH were investigated and optimized.Following desorption,the PAHs were quantified by gas chromatography with flame ionization detection(GC-FID).The limits of detection(at an S/N ratio of 3) were achieved from 0.005 to0.1 μg/L with regression coefficients(R2) higher than 0.9954.The relative standard deviations(RSDs) were below 5.8%(intraday) and 6.2%(inter-day),respectively.The method was successfully applied to the analysis of PAHs in environmental water samples where it showed recoveries in the range between 71.7%and 106.7%(with RSDs of 1.6%to 8.4%,for n = 3).The results indicated that the Fe3O4@SiO2@GO-PEA microspheres had a great promise to extraction of PAHs from different water samples.
基金financially supported by the Knowledge Innovation Program of the Chinese Academy of Sciences (Nos.KZCX2-YW-453,KZCX2-YW-JS404,and KZCX2-EW-408)the National Natural Science Foundation of China(No.41005082)the Commonweal Program of Environment Protection Department of China(No.201009004)
文摘Atmospheric fine particles (PM2.5) were collected in this study with middle volume samplers in Fuzhou, China, during both normal days and haze days in summer (September 2007) and winter (january 2008). The concentrations, distributions, and sources of polycyclic aromatic hydrocarbons (PAHs), organic carbon (OC), elemental carbon (EC), and water soluble inorganic ions (WSIls) were determinated. The results showed that the concentrations of PM2.s, PAHs, OC, EC, and WSIIs were in the orders of haze 〉 normal and winter〉 summer. The dominant PAHs of PM2.s in Fuzhou were Fluo, Pyr, Chr, BbF, BkF, BaP, BghiP, and IcdP, which represented about 80.0% of the total PAHs during different sampling periods. The BaPeq concentrations of ^-~PAHs were 0.78, 0.99, 1.22, and 2.43 ng/m3 in summer normal, summer haze, winter normal, and winter haze, respectively. Secondary pollutants (SO42 , NO3 , NH4*, and OC) were the major chemical compositions of PM2.5, accounting for 69.0%, 55.1%, 63.4%, and 64.9% of PM2.s mass in summer normal, summer haze, winter normal, and winter haze, respectively. Correspondingly, secondary organic carbon (SOC) in Fuzhou accounted for 20.1%, 48.6%, 24.5%, and 50.5% of OC. The average values of nitrogen oxidation ratio (NOR) and sulfur oxidation ratio (SOR) were higher in haze days (0.08 and 0.27) than in normal days (0.05 and 0.22). Higher OC/EC ratios were also found in haze days (5.0) than in normal days (3.3). Correlation analysis demonstrated that visibility had positive correlations with wind speed, and neg- ative correlations with relative humidity and major air pollutants. Overall, the enrichments of PM2.5, OC, EC, SO42 ,andNO3 promoted haze formation. Furthermore, the diagnostic ratios of IcdP/(IcdP + BghiP), lcdP/BghiP, OC/EC, and NO3 /SO42 indicated that vehicle exhaust and coal consumption were the main sources of pollutants in Fuzhou.
