Abstract:
In this study, a simple volumetric and sound velocity method was used for the analysis of
effect of vitamin B6 (pyridoxine) on the structure of amino acids (L-serine, L-asparagine
and L-glutamine). Densities and sound velocities of L-serine, L-asparagine and
L-glutamine in aqueous and in aqueous 0.05 mol.kg-1, 0.20 mol.kg-1, 0.35 mol.kg-1 and
0.50 mol.kg-1 vitamin B6 solutions have been studied at 293.15K to 318.15K with an
interval of 5K. The density data have been used to calculate apparent molar volume (φv),
limiting apparent molar volume (φv0), limiting apparent molar volume transfer (Δtrφv0),
apparent molar expansibilities (Eφ0) and Helper’s constant (δEφ0/δT)p. The ultrasonic
properties such as adiabatic compressibility (βs), apparent molar adiabatic compressibility
(φk0), limiting apparent molar adiabatic compressibility (φk0), apparent molar adiabatic
compressibility of transfer (Δtrφk0), acoustic impedance (Z) and hydration number (nH)
have been calculated by densities and sound velocities data.
The densities increase with the increase of concentration of amino acids. Densities of
amino acids in aqueous vitamin B6 solutions are higher than that of amino acids in
aqueous solution. The limiting apparent molar volumes (φv0) are positive at the studied
temperatures for the binary and ternary mixtures indicate the presence of solute-solvent
interactions. The smaller values of experimental slope (Sv) as compared to φv0 values
suggest the dominance of solute-solvent interaction over the solute-solute interaction.
The limiting apparent molar volume transfer (Δtrφv0) values of L-glutamine and
L-asparagine in aqueous 0.2 mol.kg-1, 0.35 mol.kg-1 and 0.5 mol.kg-1 vitamin B6 solution
are negative which suggest the dominance of ion-hydrophobic and hydrophobichydrophobic
interactions. But Δtrφv0 values of L-serine in aqueous 0.05 mol.kg-1, 0.20
mol.kg-1, 0.35 mol.kg-1 and 0.50 mol.kg-1 vitamin B6 solutions positive which suggest the
dominance of ion-hydrophilic and hydrophilic-hydrophilic interactions. The values of
limiting apparent molar expansion (Eφ0) are positive. The Hepler’s constant (δEφ0/δT)p
values of binary system are small negative for all studied amino acids. In ternary systems,
the Hepler’s constant values are mainly positive. This suggest that amino acids in ternary
solution are more structural than binary solution. The values of partial molar volumes (V2)
increase with increasing of concentration of L-serine, L-asparagine and L-glutamine for
the studied systems.
The sound velocity increases with the increase of concentration of amino acids (L-serine,
L-asparagine and L-glutamine). Sound velocities of amino acids in aqueous vitamin B6
solutions are higher than that of amino acids in aqueous solution. This indicate that the
increase of compactness of the medium with the increase in amino acids and vitamin B6
concentration.
The adiabatic compressibility (βs) decreases with the increase of concentration of amino
acids. This indicates the water molecules around the amino acids are less compressible
than the water molecules in the bulk solution. The negative apparent molar adiabatic
compressibility (φk) values indicate the greater loss of structural compressibility of water.
The values of limiting apparent molar adiabatic compressibility (φk0) are negative. The
values of apparent molar adiabatic compressibility transfer (Δtrφk
0) are mainly negative.
Negative values of Δtrφk0 indicate that increase in hydrophobic-hydrophobic and
hydrophilic-hydrophobic group interactions. The small Sk values also indicates the
dominating of solute-solvent interaction over solute-solute interaction.
The increase of acoustic impedance, Z with the increase of concentration of amino acids
indicates the presence of effective solute-solvent interactions. The positive hydration
number (nH) indicate the appreciable solvation of solutes.
Description:
This thesis is submitted to the Department of Chemistry, Khulna University of Engineering & Technology in partial fulfillment of the requirements for the degree of Master of Science in Chemistry, March 2018.
Cataloged from PDF Version of Thesis.
Includes bibliographical references (pages 177-184).