Volumetric properties of dilute (d-glucose + H2O) solutions at temperatures from (293.15 to 433.15) K and pressures from (0.10 to 50.00) MPa
Seitz, Jeffery; Schulte, Mitch; Hall, Ashley; Rhett, Garret (2019), Volumetric properties of dilute (d-glucose + H2O) solutions at temperatures from (293.15 to 433.15) K and pressures from (0.10 to 50.00) MPa, Dryad, Dataset, https://doi.org/10.5061/dryad.djh9w0vw9
The densities of aqueous solutions of D-glucose were measure at temperatures from (293.15 to 433.15) K and pressures from (0.10 to 50.00) MPa using a vibrating-tube densimeter. Apparent molar volumes Vφ,m and partial molar volumes at infinite dilution V∞ were calculated from the experimental results. V∞ increases as temperature increases and varies linearly with temperature above ~300 K. In addition, V∞ does not vary as a function of pressure up to 50.0 MPa. Comparison of these results with previous studies indicate excellent agreement and significantly extend the experimental database for aqueous solutions of D-glucose to elevated temperatures and pressures.
Density measurements were obtained with a commercially available Anton Paar vibrating-tube densimeter (DMA HP). A high pressure fluid manifold was constructed to deliver the fluids to the densimeter. Densities of pure water and aqueous D-glucose solutions were experimentally measured. The apparent molar volumes calculated from the experimentally-determined density data using the molar mass of D-glucose (180.15588 g·mol-1). The partial molar volume at infinite dilution was determined from the intercept of a least squares fit of the apparent molar volume (at constant pressure and temperature).
Data include densities, apparant molar volumes and partial molar volumes for D-glucose solutions.
Uncertainty in density is ±0.0001.
Uncertainty in apparent molar volume varies as a function of concentration. See fig. 4.
Uncertainty in parial molar volume at infinite dilution is ±1.0 cm3/mol.
NASA Astrobiology: Exobiology and Evolutionary Biology Program, Award: NNX07AT84G, NNX11AO62G