The layered Li2MnO3 is investigated by using the first-principles calculations within the GGA and GGA-t-U scheme, respectively. Within the GGA4-U approach, the calculated intercalation voltage (ranges from 4,5 V to 4...The layered Li2MnO3 is investigated by using the first-principles calculations within the GGA and GGA-t-U scheme, respectively. Within the GGA4-U approach, the calculated intercalation voltage (ranges from 4,5 V to 4.9 V) is found to be in good agreement with experiments. From the analysis of electronic structure, the pure phase Li2MnO3 is insulating, which is indicative of poor electronic-conduction properties. However, further studies of lithium ion diffusion in bulk Li2MnO3 show that unlike the two-dimensional diffusion pathways in rock salt structure layered cathode materials, lithium can diffuse in a three-dimensional pathway in Li2MnO3, with moderate lithium migration energy barrier ranges from 0.57 to 0.63 e V.展开更多
The lattice dynamic, elastic, and thermodynamic properties of Be Se were investigated with first principles calculations. The phase transition pressure from the zinc blende(B3) to the nickel arsenide(B8) structure...The lattice dynamic, elastic, and thermodynamic properties of Be Se were investigated with first principles calculations. The phase transition pressure from the zinc blende(B3) to the nickel arsenide(B8) structure of Be Se was determined. The elastic stability analysis suggests that the B3 structure Be Se is mechanically stable in the applied pressure range of 0-50 GPa. Our lattice dynamic calculations show that the B3 structure is lattice dynamically stable under high pressure. Within the quasiharmonic approximation, the thermodynamic properties including the constant volume heat capacity and constant pressure heat capacity are predicted.展开更多
Understanding the mechanisms and properties of various transport processes in the electrolyte,porous electrode,and at the interface between electrode and electrolyte plays a crucial role in guiding the improvement of ...Understanding the mechanisms and properties of various transport processes in the electrolyte,porous electrode,and at the interface between electrode and electrolyte plays a crucial role in guiding the improvement of electrolytes,materials and microstructures of electrode.Nanoscale equilibrium properties and nonequilibrium ion transport are substantially different to that in the bulk,which are difficult to observe from experiments directly.In this paper,we introduce equilibrium and no-equilibrium thermodynamics for electrolyte in porous electrodes or electrolyte-electrode interface.The equilibrium properties of electrical double layer(EDL)including the EDL structure and capacitance are discussed.In addition,classical non-equilibrium thermodynamic theory is introduced to help us understand the coupling effect of different transport processes.We also review the recent studies of nonequilibrium ion transport in porous electrode by molecular and continuum methods,among these methods,dynamic density functional theory(DDFT)shows tremendous potential as its high efficiency and high accuracy.Moreover,some opportunities for future development and application of the non-equilibrium thermodynamics in electrochemical system are prospected.展开更多
Here we present a combined DFF and molecular dynamics study of uranyl (U(VI)) interaction mecha- nisms with the calcite (104) surface in aqueous solution. The roles of three anion ligands (CO2 , HCO3, OH ) and...Here we present a combined DFF and molecular dynamics study of uranyl (U(VI)) interaction mecha- nisms with the calcite (104) surface in aqueous solution. The roles of three anion ligands (CO2 , HCO3, OH ) and solvation effect in U(VI) interaction with calcite have been evaluated. According to our calculations, water adsorbed on the calcite (104) surface prefers to exist in molecular state rather than dis- sociative state. Energy analysis indicate that the positively charged uranyl species prefers to form surface complexes on the surface, while neutral uranyl species may bind with the surface via both surface complexing and ion exchange reactions of U(VI) → Ca(II). In contrast, the negatively charged uranyl species prefer to interact with the surface via ion exchange reactions of U(VI)→ Ca(II), and the one with UO2(CO3)2(H2O)^2- as the reactant becomes the most favorable one in energy. We also found that uranyl adsorption increases the hydrophilicability of the (104) surface to different extents, where the UO2(CO3)3Ca2 species contributes to the largest degree of energy changes ( 53 kcal/mol). Our calcula- tions proved that the (104) surface also has the ability to immobilize U(VI) via either surface complexing or ion exchange mechanisms under different pH values.展开更多
The physicochemical properties of surfaces have a great effect on the micro-morphologies of the crystal structures which are in contact with them.Understanding the interaction mechanism between the internal driving fo...The physicochemical properties of surfaces have a great effect on the micro-morphologies of the crystal structures which are in contact with them.Understanding the interaction mechanism between the internal driving forces of the crystal and external inducing forces of the surfaces is the prerequisite of controlling and obtaining the desirable morphologies.In this work,the dynamic density functional theory was applied to construct the free energy functional expression of polyethylene(PE)lattice,and the micro-dynamic evolution processes of PE lattice morphology near the surfaces with different properties were observed to reveal the interaction mechanism at atomic scale.The results showed that the physical and chemical properties of the external surfaces synergistically affect the morphologies in both the defect shapes and the distribution of the defect regions.In the absence of the contact surfaces,driven by the oriented interactions among different CH2 groups,PE lattices gradually grow and form a defect-free structure.Conversely,the presence of contact surfaces leads to lattice defects in the interfacial regions,and PE lattice shows different self-healing abilities around different surfaces.展开更多
The effect of steady shear on multi-axial texture of symmetric diblock copolymer was investigated by using dynamic density functional theory.Through modifying the periodic boundary condition,the parallel-transverse bi...The effect of steady shear on multi-axial texture of symmetric diblock copolymer was investigated by using dynamic density functional theory.Through modifying the periodic boundary condition,the parallel-transverse biaxial texture and perpendicular-parallel-transverse triaxial texture have been observed.In the formation of the multi-axial texture,there are two critical velocities uper-par and upartra,at which the transition between the perpendicular and the parallel lamellar morphology,and the transition between the parallel and the transverse lamellar morphology occur,respectively.The two critical velocities increase as the inter-action parameter increases,but they almost remain constant at different shear rates.Furthermore,the rotation from the transverse lamellae to the parallel lamellae induced by the shear strain,and the increase of lamellar spacings of the three lamellae after removing the shear,have also been observed by the time evolution of the morphologies.These phenomena are consistent with experimental work.展开更多
基金Supported by the National Natural Science Foundation of China under Grant No 21363016the Natural Science Foundation of Jiangxi Province under Grant No 20142BAB216030the PhD Early Development Program of Nanchang Hangkong University under Grant No EA201502007
文摘The layered Li2MnO3 is investigated by using the first-principles calculations within the GGA and GGA-t-U scheme, respectively. Within the GGA4-U approach, the calculated intercalation voltage (ranges from 4,5 V to 4.9 V) is found to be in good agreement with experiments. From the analysis of electronic structure, the pure phase Li2MnO3 is insulating, which is indicative of poor electronic-conduction properties. However, further studies of lithium ion diffusion in bulk Li2MnO3 show that unlike the two-dimensional diffusion pathways in rock salt structure layered cathode materials, lithium can diffuse in a three-dimensional pathway in Li2MnO3, with moderate lithium migration energy barrier ranges from 0.57 to 0.63 e V.
基金Funded by the National Natural Science Foundation of China(Nos.11447176 and 11447152)the The National Scholastic Athletics Foundation(No.U1230201)the Doctor Foundation of Southwest University of Science and Technology(Nos.13zx7137 and 14zx7167)
文摘The lattice dynamic, elastic, and thermodynamic properties of Be Se were investigated with first principles calculations. The phase transition pressure from the zinc blende(B3) to the nickel arsenide(B8) structure of Be Se was determined. The elastic stability analysis suggests that the B3 structure Be Se is mechanically stable in the applied pressure range of 0-50 GPa. Our lattice dynamic calculations show that the B3 structure is lattice dynamically stable under high pressure. Within the quasiharmonic approximation, the thermodynamic properties including the constant volume heat capacity and constant pressure heat capacity are predicted.
基金sponsored by the National Natural Science Foundation of China(No.91834301,21808055)National Natural Science Foundation of China for Innovative Research Groups(No.)+1 种基金the Shanghai Sailing Program(18YF1405400)EU-FET project NANOPHLOW0(REP-766972-1)。
文摘Understanding the mechanisms and properties of various transport processes in the electrolyte,porous electrode,and at the interface between electrode and electrolyte plays a crucial role in guiding the improvement of electrolytes,materials and microstructures of electrode.Nanoscale equilibrium properties and nonequilibrium ion transport are substantially different to that in the bulk,which are difficult to observe from experiments directly.In this paper,we introduce equilibrium and no-equilibrium thermodynamics for electrolyte in porous electrodes or electrolyte-electrode interface.The equilibrium properties of electrical double layer(EDL)including the EDL structure and capacitance are discussed.In addition,classical non-equilibrium thermodynamic theory is introduced to help us understand the coupling effect of different transport processes.We also review the recent studies of nonequilibrium ion transport in porous electrode by molecular and continuum methods,among these methods,dynamic density functional theory(DDFT)shows tremendous potential as its high efficiency and high accuracy.Moreover,some opportunities for future development and application of the non-equilibrium thermodynamics in electrochemical system are prospected.
基金supported by the National Natural Science Foundation of China (U1507116, 21471152, and 21477130)the Major Research Plan of Natural Science Foundation of China (91326202)The Science Challenge Project of China (JCKY2016212A504) is also acknowledged
文摘Here we present a combined DFF and molecular dynamics study of uranyl (U(VI)) interaction mecha- nisms with the calcite (104) surface in aqueous solution. The roles of three anion ligands (CO2 , HCO3, OH ) and solvation effect in U(VI) interaction with calcite have been evaluated. According to our calculations, water adsorbed on the calcite (104) surface prefers to exist in molecular state rather than dis- sociative state. Energy analysis indicate that the positively charged uranyl species prefers to form surface complexes on the surface, while neutral uranyl species may bind with the surface via both surface complexing and ion exchange reactions of U(VI) → Ca(II). In contrast, the negatively charged uranyl species prefer to interact with the surface via ion exchange reactions of U(VI)→ Ca(II), and the one with UO2(CO3)2(H2O)^2- as the reactant becomes the most favorable one in energy. We also found that uranyl adsorption increases the hydrophilicability of the (104) surface to different extents, where the UO2(CO3)3Ca2 species contributes to the largest degree of energy changes ( 53 kcal/mol). Our calcula- tions proved that the (104) surface also has the ability to immobilize U(VI) via either surface complexing or ion exchange mechanisms under different pH values.
基金supported by the National Natural Science Foundation of China(Nos.21476007,21673197,21621091)the National Key R&D Program of China(No.2018YFA0209500)+4 种基金the 111 Project(No.B16029)the Fundamental Research Funds for the Central Universities of China(No.20720190037)the Natural Science Foundation of Fujian Province of China(No.2018J06003)the Special Project of Strategic Emerging Industries from Fujian Development and Reform CommissionChemcloudcomputing of Beijing University of Chemical Technology。
文摘The physicochemical properties of surfaces have a great effect on the micro-morphologies of the crystal structures which are in contact with them.Understanding the interaction mechanism between the internal driving forces of the crystal and external inducing forces of the surfaces is the prerequisite of controlling and obtaining the desirable morphologies.In this work,the dynamic density functional theory was applied to construct the free energy functional expression of polyethylene(PE)lattice,and the micro-dynamic evolution processes of PE lattice morphology near the surfaces with different properties were observed to reveal the interaction mechanism at atomic scale.The results showed that the physical and chemical properties of the external surfaces synergistically affect the morphologies in both the defect shapes and the distribution of the defect regions.In the absence of the contact surfaces,driven by the oriented interactions among different CH2 groups,PE lattices gradually grow and form a defect-free structure.Conversely,the presence of contact surfaces leads to lattice defects in the interfacial regions,and PE lattice shows different self-healing abilities around different surfaces.
文摘The effect of steady shear on multi-axial texture of symmetric diblock copolymer was investigated by using dynamic density functional theory.Through modifying the periodic boundary condition,the parallel-transverse biaxial texture and perpendicular-parallel-transverse triaxial texture have been observed.In the formation of the multi-axial texture,there are two critical velocities uper-par and upartra,at which the transition between the perpendicular and the parallel lamellar morphology,and the transition between the parallel and the transverse lamellar morphology occur,respectively.The two critical velocities increase as the inter-action parameter increases,but they almost remain constant at different shear rates.Furthermore,the rotation from the transverse lamellae to the parallel lamellae induced by the shear strain,and the increase of lamellar spacings of the three lamellae after removing the shear,have also been observed by the time evolution of the morphologies.These phenomena are consistent with experimental work.
