Abstract
Introduction:: The aim of this study is to determine the acoustic parameters of polymer dextran with urea. Recent years have seen an increase in the use of ultrasonic research to describe the physiochemical and thermodynamic characteristics of liquid solutions at various temperatures and frequencies. The size of the pure component and the mixtures had an impact on various interactions, molecular mobility, and kinds of interaction. Which were studied using the acoustical and thermodynamic characteristics? To ascertain how the solvent urea interacts with the solute dextran at the molecular level. Materials and Method: Dextran (molecular weight of 70000) with 6(M)urea was used. The solution's density using a pycnometer, viscosity using an Ostwald viscometer, and ultrasonic velocity using an ultrasonic interferometer were examined. Results:: The physical properties of the medium are affected by the transmission of ultrasonic waves, which also teaches us about the physics of liquids and solutions. Understanding the interactions between the solutes and the solvent in the solution of dextran and urea, both the evaluated parameters were used, such as free volume, internal pressure, absorption coefficient, Rao's constant, and Wada's constant, as well as the observed values, such as ultrasonic velocity, density, and viscosity. Conclusion:: Based on the modification of these parameters with varied temperature and frequency, molecular mobility, different types of intermolecular interaction, and the strength of the bond between the solute (dextran 0.5%) and solvent (6(M) urea) are investigated. The findings have been explained in terms of a structural reorganisation in the aqueous dextran solution. At all the temperatures used for the investigation, the solute-solvent interactions are more significant. The change in the acoustic properties is small because the frequency variation causes the molecules to move swiftly and have little chance to interact. Investigating molecular interactions, including electrostriction, acceptor-donor association, dipole-dipole association, and hydrogen bonding, has used these properties. Understanding molecular interactions helps one to comprehend the core issues surrounding the mechanisms of chemical and biological catalysis and the routes of chemical reactions.
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