Climate warming and nitrogen (N) deposition change ecosystem processes, structure, and functioning whereas the phosphorus (P) composition and availability directly influence the ecosystem structure under condi- ti...Climate warming and nitrogen (N) deposition change ecosystem processes, structure, and functioning whereas the phosphorus (P) composition and availability directly influence the ecosystem structure under condi- tions of N deposition. In our study, four treatments were designed, including a control, diurnal warming (DW), N deposition (ND), and combined warming and N deposition (WN). The effects of DW, ND, and WN on P composition were studied by 3~p nuclear magnetic resonance (3~p NMR) spectroscopy in a temperate grassland region of China. The results showed that the N deposition decreased the soil pH and total N (TN) concentration but increased the soil OIsen-P concentration. The solution-state 31p NMR analysis showed that the DW, ND and WN treatments slightly decreased the proportion of orthophosphate and increased that of the monoesters. An absence of myo-inositol phosphate in the DW, ND and WN treatments was observed compared with the control. Furthermore, the DW, ND and WN treatments significantly decreased the recovery of soil P in the NaOH-EDTA solution by 17%-20%. The principal component analysis found that the soil pH was positively correlated with the P recovery in the NaOH-EDTA solution. Therefore, the decreased soil P recovery in the DW and ND treatments might be caused by an indirect influence on the soil pH. Additionally, the soil moisture content was the key factor limiting the available P. The positive correlation of total carbon (TC) and TN with the soil P composition indicated the influence of climate warming and N deposition on the biological processes in the soil P cycling.展开更多
Photocatalytic reduction of heavy metal ions is a green and promising technology which requires electrons with enough negative energy levels as well as efficient separation property from photo-generated holes of photo...Photocatalytic reduction of heavy metal ions is a green and promising technology which requires electrons with enough negative energy levels as well as efficient separation property from photo-generated holes of photocatalysts.For WO_(3),the low conduction band edge and the severe photo-generated charge carrier recombination limited its application in photocatalytic reduction of pollutants.In this work,we prepared WO_(3)@PVP with PVP capped WO_(3) by a simple one-step hydrothermal method,which showed an elevated energy band structure and improved charge carrier separation property.XRD,SEM,TEM,XPS,DRS,and the photocurrent density test were carried out to study the properties of the composite.Results demonstrated monoclinic WO_(3) with a size of~100-250 nm capped by PVP was obtained,which possessed fewer lattice defects inside but more defects(W^(5+))on the surface.Moreover,the results of the photocatalytic experiment showed the kinetic constant of Cr(Ⅵ)reduction process on WO_(3)@PVP was 0.532 h^(-1),which was 3.1 times higher than that onWO_(3)(0.174 h^(-1)),demonstratingWO_(3)@PVP with good photocatalytic capability for Cr(Ⅵ)reduction.This can be attributed to the improved charge carrier separation performance,the improved adsorption capacity and the elevated conduction band edge of WO_(3)@PVP.More importantly,the energy band structure of WO_(3)@PVP was proved elevated with a value as high as 1.14 eV than that of WO_(3) nanoparticles,which enables WO_(3)@PVP a promising material in the photocatalytic reduction reaction of heavy metal ions from wastewater.展开更多
基金National Natural Science Foundation of China(41171241)the National Basic Research Program of China(2011CB403204)
文摘Climate warming and nitrogen (N) deposition change ecosystem processes, structure, and functioning whereas the phosphorus (P) composition and availability directly influence the ecosystem structure under condi- tions of N deposition. In our study, four treatments were designed, including a control, diurnal warming (DW), N deposition (ND), and combined warming and N deposition (WN). The effects of DW, ND, and WN on P composition were studied by 3~p nuclear magnetic resonance (3~p NMR) spectroscopy in a temperate grassland region of China. The results showed that the N deposition decreased the soil pH and total N (TN) concentration but increased the soil OIsen-P concentration. The solution-state 31p NMR analysis showed that the DW, ND and WN treatments slightly decreased the proportion of orthophosphate and increased that of the monoesters. An absence of myo-inositol phosphate in the DW, ND and WN treatments was observed compared with the control. Furthermore, the DW, ND and WN treatments significantly decreased the recovery of soil P in the NaOH-EDTA solution by 17%-20%. The principal component analysis found that the soil pH was positively correlated with the P recovery in the NaOH-EDTA solution. Therefore, the decreased soil P recovery in the DW and ND treatments might be caused by an indirect influence on the soil pH. Additionally, the soil moisture content was the key factor limiting the available P. The positive correlation of total carbon (TC) and TN with the soil P composition indicated the influence of climate warming and N deposition on the biological processes in the soil P cycling.
基金financially supported by the National Natural Science Foundation of China,China(21806120,51802214)China Postdoctoral Science Foundation,China(2019M651084)+4 种基金Shanxi Province Science Foundation for Youths,China(201901D211027,201801D221346)Natural Science Foundation of Shanxi Province,China(201901D111068)Key Research and Development Project of Shanxi Province,China(201903D321057,201903D321055,201703D321009-5)Science and Technology Innovation Projects of Higher School,China(201802045)School Foundation of Taiyuan University of Technology,China(2017QN22).
文摘Photocatalytic reduction of heavy metal ions is a green and promising technology which requires electrons with enough negative energy levels as well as efficient separation property from photo-generated holes of photocatalysts.For WO_(3),the low conduction band edge and the severe photo-generated charge carrier recombination limited its application in photocatalytic reduction of pollutants.In this work,we prepared WO_(3)@PVP with PVP capped WO_(3) by a simple one-step hydrothermal method,which showed an elevated energy band structure and improved charge carrier separation property.XRD,SEM,TEM,XPS,DRS,and the photocurrent density test were carried out to study the properties of the composite.Results demonstrated monoclinic WO_(3) with a size of~100-250 nm capped by PVP was obtained,which possessed fewer lattice defects inside but more defects(W^(5+))on the surface.Moreover,the results of the photocatalytic experiment showed the kinetic constant of Cr(Ⅵ)reduction process on WO_(3)@PVP was 0.532 h^(-1),which was 3.1 times higher than that onWO_(3)(0.174 h^(-1)),demonstratingWO_(3)@PVP with good photocatalytic capability for Cr(Ⅵ)reduction.This can be attributed to the improved charge carrier separation performance,the improved adsorption capacity and the elevated conduction band edge of WO_(3)@PVP.More importantly,the energy band structure of WO_(3)@PVP was proved elevated with a value as high as 1.14 eV than that of WO_(3) nanoparticles,which enables WO_(3)@PVP a promising material in the photocatalytic reduction reaction of heavy metal ions from wastewater.