Surface charges and hydration are predominant properties of colloidal particles that govern colloidal stability in aqueous suspensions.These properties usually coexist and interact with each other.The correlation betw...Surface charges and hydration are predominant properties of colloidal particles that govern colloidal stability in aqueous suspensions.These properties usually coexist and interact with each other.The correlation between the surface charge and hydration of minerals is summarized on the basis of innovative experimental,theoretical,and molecular dynamics simulation studies.The factors affecting the adsorption behavior of ions and water molecules,such as ion concentration,ion hydration radius and valence,and surface properties,are discussed.For example,the hydration and adsorption states completely differ between monovalent and divalent ions.For ions of the same valence,the effect of surface charge on the hydration force follows the Hofmeister adsorption series.Electrolyte concentration exerts a significant effect on the hydration force at high ion concentrations.Meanwhile,the ion correlations in high-concentration electrolyte systems become long range.The interfacial water structure largely depends on surface chemistry.The hydration layer between different surfaces shows large qualitative differences.展开更多
In this work,the nature of physisorbed water and its impacts on the structure,surface chemistry,and proton conduction properties of TiO2 nanocrystals were investigated by a combinational spectral technique.All TiO2 na...In this work,the nature of physisorbed water and its impacts on the structure,surface chemistry,and proton conduction properties of TiO2 nanocrystals were investigated by a combinational spectral technique.All TiO2 nanocrystals were directly prepared by a hydrothermal method,which showed highly hydrated and sulfated surfaces.The surface water molecules were indicated to exist in a wide set of energetically nonequivalent surface hydration groups,leading to the removal of physisorbed and chemisorbed water in sequence with increasing temperature.After heating treatment at 100 ℃ in air,physisorbed water layers were recovered with no significant impacts on the TiO2 nanostructure.On the other hand,when treated at the same temperature in vacuum,the recovery of physisorbed water layers was partially reversible,while a new hydration state appeared due to the filling of the high-energy adsorption sites by water molecules,which led to a significant increase in the amount of water molecules for surface hydration and an accelerated dehydration process toward lower temperature.As a result,an abnormal increase was observed in proton conductivity.These observations were explained in terms of thermally induced changes of surface chemistry and the amount of hydrated water.The results reported in this work are important,which may help understand the roles that the physisorbed water plays in stabilizing the nanostructures and therefore could have a broad class of implications.展开更多
The nanoparticles of SiO2 were used in cement systems to modify the rheological behavior, to enhance the reactivity of supplementary cementitious materials, and also to improve the strength and durability. In this res...The nanoparticles of SiO2 were used in cement systems to modify the rheological behavior, to enhance the reactivity of supplementary cementitious materials, and also to improve the strength and durability. In this research, low-cost nano-SiO2 particles from natural hydrothermal solutions obtained by membrane ultrafiltration and, optionally, by cryochemical vacuum sublimation drying, were evaluated in portland cement based systems. The SiO2-rich solutions were obtained from the wells of Mutnovsky geothermal power station (Far East of Russia). The constant nano-SiO2 dosage of 0.25% (as a solid material by weight of cementitious materials) was used to compare the cement systems with different nanoparticles against a reference mortar and a commercially available nano-SiO2. Nanoparticles were characterized by X-Ray Diffraction (XRD), BET Surface Area, Scanning Electron Microscope (SEM) and Fourier Transform Infrared (FTIR) spectroscopy techniques. It was demonstrated that the addition of polycarboxylate ether superplasticizer and the dispersion treatment using an ultrasound processor can be used to facilitate the distribution ofnano-SiOz particles in the mixing water. The effect ofnano-SiO2 particles in portland cement mortars was investigated by evaluating the flow, heat of hydration and compressive strength development. It was demonstrated that the use ofnano- SiO2 particles can reduce the segregation and improve strength properties.展开更多
基金financially supported by the National Natural Science Foundation of China(Nos.51804213,51820105006,51474167,51674183,and 51674174)the China Scholarships Council(No.201906935041)。
文摘Surface charges and hydration are predominant properties of colloidal particles that govern colloidal stability in aqueous suspensions.These properties usually coexist and interact with each other.The correlation between the surface charge and hydration of minerals is summarized on the basis of innovative experimental,theoretical,and molecular dynamics simulation studies.The factors affecting the adsorption behavior of ions and water molecules,such as ion concentration,ion hydration radius and valence,and surface properties,are discussed.For example,the hydration and adsorption states completely differ between monovalent and divalent ions.For ions of the same valence,the effect of surface charge on the hydration force follows the Hofmeister adsorption series.Electrolyte concentration exerts a significant effect on the hydration force at high ion concentrations.Meanwhile,the ion correlations in high-concentration electrolyte systems become long range.The interfacial water structure largely depends on surface chemistry.The hydration layer between different surfaces shows large qualitative differences.
基金supported by NNSFC (No.200903097,20771101)National Basic Research Program of China (No.2007CB613301,206L205)+1 种基金FIPYT (No. 2008F3116)FJIRSM (No. 2010KL002,SZD08002-3)
文摘In this work,the nature of physisorbed water and its impacts on the structure,surface chemistry,and proton conduction properties of TiO2 nanocrystals were investigated by a combinational spectral technique.All TiO2 nanocrystals were directly prepared by a hydrothermal method,which showed highly hydrated and sulfated surfaces.The surface water molecules were indicated to exist in a wide set of energetically nonequivalent surface hydration groups,leading to the removal of physisorbed and chemisorbed water in sequence with increasing temperature.After heating treatment at 100 ℃ in air,physisorbed water layers were recovered with no significant impacts on the TiO2 nanostructure.On the other hand,when treated at the same temperature in vacuum,the recovery of physisorbed water layers was partially reversible,while a new hydration state appeared due to the filling of the high-energy adsorption sites by water molecules,which led to a significant increase in the amount of water molecules for surface hydration and an accelerated dehydration process toward lower temperature.As a result,an abnormal increase was observed in proton conductivity.These observations were explained in terms of thermally induced changes of surface chemistry and the amount of hydrated water.The results reported in this work are important,which may help understand the roles that the physisorbed water plays in stabilizing the nanostructures and therefore could have a broad class of implications.
文摘The nanoparticles of SiO2 were used in cement systems to modify the rheological behavior, to enhance the reactivity of supplementary cementitious materials, and also to improve the strength and durability. In this research, low-cost nano-SiO2 particles from natural hydrothermal solutions obtained by membrane ultrafiltration and, optionally, by cryochemical vacuum sublimation drying, were evaluated in portland cement based systems. The SiO2-rich solutions were obtained from the wells of Mutnovsky geothermal power station (Far East of Russia). The constant nano-SiO2 dosage of 0.25% (as a solid material by weight of cementitious materials) was used to compare the cement systems with different nanoparticles against a reference mortar and a commercially available nano-SiO2. Nanoparticles were characterized by X-Ray Diffraction (XRD), BET Surface Area, Scanning Electron Microscope (SEM) and Fourier Transform Infrared (FTIR) spectroscopy techniques. It was demonstrated that the addition of polycarboxylate ether superplasticizer and the dispersion treatment using an ultrasound processor can be used to facilitate the distribution ofnano-SiOz particles in the mixing water. The effect ofnano-SiO2 particles in portland cement mortars was investigated by evaluating the flow, heat of hydration and compressive strength development. It was demonstrated that the use ofnano- SiO2 particles can reduce the segregation and improve strength properties.
