Your search keyword '"Yu, Yi"' showing total 2 results

1. Dissolution behavior, thermodynamic analysis and molecular simulation of lithium bis(fluorosulfonyl)imide in organic solvent at 273.15 K to 313.15 K.

Author

Fang, Xin, Mei, Bolun, Yang, Xingchuan, Yu, Yi, Cao, Chunmei, Xu, Li, and Liu, Guoji

Subjects

*THERMODYNAMICS, *ELECTROLYTE solutions, *BUTYL acetate, *HEAT radiation & absorption, *ORGANIC solvents, *MOLECULAR dynamics, *ORGANOLITHIUM compounds

Abstract

[Display omitted] • The solubility of LiFSI in 11 organic solvents was determined. • Different thermodynamics models were used to correlate the solubility data. • Thermodynamic properties of LiFSI solution were calculated. • Molecular simulation was used to analyze the dissolution behavior of LiFSI. The solubility of LiFSI in ethanol, n-propanol, isopropanol, n-butanol, methyl acetate, ethyl acetate, propyl acetate, butyl acetate, dimethyl carbonate, ethyl methyl carbonate, diethyl carbonate at 273.15 K to 313.15 K were determined. Elevated temperatures can actuate the continued mixing of LIFSI in the 11 fluids outlined above. In comparison, the addition of an alkyl group to the carbon chain of a structurally similar solvent molecule will result in a smaller solubility of LiFSI. Overall the molar solubility of LiFSI in esters are significantly higher than the other four alcohols. Besides, the corresponding theoretical results were mounted by fitting the classical equation. The deviation of the fitted values from the measured values showed that the Apelblat equation and Yaws model was more effectively in fitting the solubility of LiFSI. Then, The Δ sol H o, Δ sol G o, Δ sol S o of electrolyte solution were discussed by Van't Hoff equation. Their fruits implied that the dissolution of LiFSI is found to be accompanied by heat absorption and entropy gain processes. Finally, the solvent molecular polarity index and solvation free energy were calculated by molecular visualization analysis and molecular dynamics simulation, and the correlation analysis with solubility order was carried out to illustrate the role of molecular features on the LiFSI solubility was explained. Electrostatic interactions and molecular polarity are the leading players in determining its solubility limit. These results will provide valuable reference for the purification of LiFSI and the development of new electrolyte solutions. [ABSTRACT FROM AUTHOR]

Published

2024

2. 2,3-Dichloropyridine solubility in 14 pure solvents: Determination, correlation, Hansen solubility parameter, solvent effect and thermodynamic analysis.

Author

Li, Fanfan, Chen, Yulu, Li, Yanxun, Wan, Yameng, Gao, Xiaoqiang, Xiao, Jian, Ma, Shuxiu, and Yu, Yi

Subjects

*THERMODYNAMICS, *SOLUBILITY, *BUTYL acetate, *SOLVENTS, *ISOBUTANOL, *ETHYL acetate, *HEXANE

Abstract

• Solubility of 2,3-dichloropyridine in 14 pure solvents were measured. • Solubility modeling was realized by seven thermodynamic models. • Hansen solubility parameters were employed to explain solubility behaviors. • Solvent effect was studied by MEPs, Hirshfeld surface analysis and DFT calculation. • Thermodynamic properties were discussed by Van't Hoff equation. The solid–liquid equilibrium data of 2,3-dichloropyridine(23DCP) in 14 pure solvents were measured making use of the laser dynamic monitoring at 278.15/283.15/288.15 K − 313.15 K with 0.1 MPa. The findings of this study showed that the solubility increase of 23DCP in 14 pure solvents had a positive relation with temperature, and the solubility order was 1,4-dioxane > dichloromethane > n-butyl acetate > ethyl acetate > methyl acetate > acetonitrile > n-butanol > isobutyl alcohol > n-propanol > isopropanol > ethanol > cyclohexane > methanol > n-hexane. The solubility data of 23DCP was operated by seven models (Van't Hoff, modified Apelblat, λh, Yaws, NRTL, NRTL-SAC, Wilson) to correlate. And the average ARD values were 1.684 %,1.058 %, 1.031 %, 0.905 %, 0.937 %, 1.012 %, 2.062 % and the average 103RMSD values were 1.978, 1.396, 1.542, 1.221, 1.758, 1.658 and 1.883, respectively. In addition, Hansen solubility parameters were well evaluated to appraise the miscibility of 23DCP in 14 pure solvents. And the interactions between molecules were studied by means of molecular electrostatic potential surface, Hirshfeld surface analysis and density functional theory calculation. Finally, according to Van't Hoff equation, Δ sol G °, Δ sol H ° and Δ sol S ° of 23DCP in 14 pure solvents were got. Δ sol H ° and Δ sol S ° were bigger than zero, representing that this was a dissolution process of endothermic and entropy increase. [ABSTRACT FROM AUTHOR]

Published

2024