Equilibria Data for the CO2 + Ethanol + Ketoprofen Systems – Experimental and Modeling

IF 1.4 4区 化学 Q4 CHEMISTRY, PHYSICAL
José Vinicius Mattos, Matías José Molina, Sabrina Belén Rodriguez-Reartes, Leandro Ferreira-Pinto, Marcelo Santiago Zabaloy, Lúcio Cardozo-Filho
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Abstract

This study investigated the solid–fluid and vapor–liquid equilibrium of varying the molar fraction of ketoprofen in binary system (CO2 + ketoprofen), 3.14 × 10–5, 4.70 × 10–5 and 8.11 × 10–5, and the concentration of ketoprofen in ternary system (CO2 + ethanol + ketoprofen), 0.05073 and 0.10277 molKetoprofen·kgethanol−1, on a CO2-free basis for both systems. The aim was to study the solubility of ketoprofen at different molar fractions and predict its behavior over a wide range of temperatures and pressures by means of thermodynamic modeling. Experiments were conducted as a function of temperature from 313 to 333 K and pressure up to 14 MPa, using a visual synthetic static method with a variable volume cell. The collected data highlight an increase of the ketoprofen solubility with the temperature, while a ketoprofen content has a low impact on the bubble point pressure of the tested ternary system. Data were then correlated by using the thermodynamic modeling employed the Redlich–Kwong–Peng–Robinson equation of state (RK–PR EoS) with quadratic mixing rules for fluid phases and a pure solid model for ketoprofen. Then, a number of complete isopleths at set global composition were computed for the CO2 + ketoprofen binary system being indicated solid–fluid, solid–fluid–fluid, and fluid–fluid regions. The obtained results suggest that the thermodynamic models used in this work were able to describe the experimentally observed phase behavior.

Graphical Abstract

Abstract Image

二氧化碳+乙醇+酮洛芬体系的平衡数据--实验和建模
本研究以无二氧化碳为基础,研究了改变二元体系(二氧化碳+酮洛芬)中酮洛芬的摩尔分数(3.14 × 10-5、4.70 × 10-5和8.11 × 10-5)和三元体系(二氧化碳+乙醇+酮洛芬)中酮洛芬的浓度(0.05073和0.10277 molKetoprofen-kethanol-1)时的固液平衡和汽液平衡。目的是研究酮洛芬在不同摩尔分数下的溶解度,并通过热力学模型预测其在各种温度和压力下的行为。实验采用可视化合成静态法,使用可变容积池,温度范围为 313 至 333 K,压力范围为 14 MPa。收集到的数据表明,酮洛芬的溶解度随温度升高而增加,而酮洛芬含量对测试三元体系的气泡点压力影响较小。然后,利用热力学模型对数据进行了关联,该模型采用了 Redlich-Kwong-Peng-Robinson 状态方程(RK-PR EoS),其中流体相采用二次混合规则,酮洛芬采用纯固体模型。然后,计算了二氧化碳+酮洛芬二元体系在设定全局成分下的若干完整等值线,分别表示固-流体、固-流体-流体和流-流体区域。结果表明,这项工作中使用的热力学模型能够描述实验观察到的相行为。
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来源期刊
Journal of Solution Chemistry
Journal of Solution Chemistry 化学-物理化学
CiteScore
2.30
自引率
0.00%
发文量
87
审稿时长
3-8 weeks
期刊介绍: Journal of Solution Chemistry offers a forum for research on the physical chemistry of liquid solutions in such fields as physical chemistry, chemical physics, molecular biology, statistical mechanics, biochemistry, and biophysics. The emphasis is on papers in which the solvent plays a dominant rather than incidental role. Featured topics include experimental investigations of the dielectric, spectroscopic, thermodynamic, transport, or relaxation properties of both electrolytes and nonelectrolytes in liquid solutions.
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