Determination of partial propagation velocity and partial isentropic compressibility coefficient in water–ethanol system

This study introduces an innovative approach to the layered model, emphasizing the physical–chemical characterization of miscible liquid systems through ultrasonic techniques, with a specific focus on the water–ethanol system used in pharmaceutical formulations. Traditional characterization methods,...

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Autores:
Franco Guzmán, Ediguer Enrique
Reyna, Carlos A. B.
Lopes, Jose H.
Tsuzuki, Marcos S. G.
Buiochi, Flávio
Tipo de recurso:
Article of investigation
Fecha de publicación:
2024
Institución:
Universidad Autónoma de Occidente
Repositorio:
RED: Repositorio Educativo Digital UAO
Idioma:
eng
OAI Identifier:
oai:red.uao.edu.co:10614/16209
Acceso en línea:
https://hdl.handle.net/10614/16209
https://doi.org/10.3390/s24134061
https://red.uao.edu.co/
Palabra clave:
Velocidad de propagación
Modelos estratificados
Agua-etanol
Propiedades parciales
Propagation velocity
Layered models
Water–ethanol
Partial properties
Rights
openAccess
License
Derechos reservados - MDPI, 2024
Description
Summary:This study introduces an innovative approach to the layered model, emphasizing the physical–chemical characterization of miscible liquid systems through ultrasonic techniques, with a specific focus on the water–ethanol system used in pharmaceutical formulations. Traditional characterization methods, while effective, face challenges due to the complex nature of solutions, such as the need for large pressure variations and strict temperature control. The proposed approach integrates partial molar volumes and partial propagation velocity functions into the layered model, enabling a nuanced understanding of miscibility and interactions. Ultrasonic techniques are used to calculate the isentropic compressibility coefficient for each component of the mixture as well as the total value using an additive mixing rule. Unlike conventional methods, this technique uses tabulated and experimental data to estimate the propagation velocity in the mixture, leading to a more precise computation of the isentropic compressibility coefficient. The results indicate a significant improvement in predicting the behavior of the water–ethanol system compared to the classical layered model. The methodology demonstrates the potential to provide new physicochemical insights that can be applied to other miscible systems beyond water–ethanol. This research has implications for improving the efficiency and accuracy of liquid medication formulations in the pharmaceutical industry

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