Thermodynamics Research Center / ThermoML | Journal of Chemical Thermodynamics

Thermochemistry of 2- and 4-biphenylmethanol

Pinto, S. S.[Susana S.], Bernardes, C. E. S.[Carlos E. S.], Diogo, H. P.[Herminio P.], Minas de Piedade, M. E.[Manuel E.]
J. Chem. Thermodyn. 2007, 39, 10, 1384-1391
ABSTRACT
The standard (p = 0.1 MPa) molar enthalpies of formation of 2-biphenylmethanol (2BPM) and 4-biphenylmethanol (4BPM) in the crystalline state, at T = 298.15 K, were determined by static-bomb combustion calorimetry as DfH mo2BPM; crP 1/4 o107:9 3:7P kJ Ae mol 1 and DfH mo4BPM; crP 1/4 o121:5 4:2P kJ Ae mol 1, respectively. The corresponding enthalpies of sublimation, DsubH mo2BPMP 1/4 o107:1 0:6P kJ Ae mol 1 and DsubH mo4BPMP 1/4 o107:3 1:8P kJ Ae mol 1, were obtained by Calvet drop microcalorimetry and Knudsen-effusion vapour-pressure measurements. From the above results it was possible to derive DfH mo2BPM; gP 1/4 o0:8 3:7P kJ Ae mol 1, DfH mo4BPM; gP 1/4 o14:2 4:6P kJ Ae mol 1. These values, in conjunction with the experimental enthalpies of formation of benzene, biphenyl, and benzyl alcohol taken from the literature, were used to assess the predictions of the MPW1PW91/ 6-31G(d), B3LYP/6-31G(d), and B3LYP/6-311+G(d,p) methods for the enthalpy of isodesmic and isogyric reactions involving those species. This test supported the reliability of the theoretical methods, and indicated a good thermodynamic consistency between the DfH mogP values obtained in this work for the two biphenylmethanol isomers and the corresponding data for benzene, biphenyl, and benzyl alcohol selected from the literature. Finally, the similarity between the obtained enthalpies of sublimation of 2BPM and 4BPM indicates that, despite structural differences in the crystalline state, the two compounds have comparable lattice energies at T = 298.15 K.
Compounds
# Formula Name
1 CO2 carbon dioxide
2 H2O water
3 O2 oxygen
4 C13H12O 2-biphenylmethanol
5 C13H12O 4-biphenylmethanol
Datasets
The table above is generated from the ThermoML associated json file (link above). POMD and RXND refer to PureOrMixture and Reaction Datasets. The compound numbers are included in properties, variables, and phases, if specificied; the numbers refer to the table of compounds on the left.
Type Compound-# Property Variable Constraint Phase Method #Points
  • POMD
  • 4
  • Molar enthalpy of transition or fusion, kJ/mol ; Crystal
  • Crystal
  • Liquid
  • Air at 1 atmosphere
  • DSC
  • 1
  • POMD
  • 4
  • Normal melting temperature, K ; Crystal
  • Crystal
  • Liquid
  • Air at 1 atmosphere
  • DTA
  • 1
  • POMD
  • 4
  • Molar heat capacity at constant pressure, J/K/mol ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • Drop calorimetry
  • 1
  • POMD
  • 4
  • Vapor or sublimation pressure, kPa ; Crystal
  • Temperature, K; Crystal
  • Crystal
  • Gas
  • Calculated from knudsen effusion weight loss
  • 8
  • POMD
  • 4
  • Molar enthalpy of vaporization or sublimation, kJ/mol ; Crystal
  • Temperature, K; Crystal
  • Crystal
  • Gas
  • Static calorimetry
  • 1
  • POMD
  • 5
  • Molar enthalpy of transition or fusion, kJ/mol ; Crystal
  • Crystal
  • Liquid
  • Air at 1 atmosphere
  • DSC
  • 1
  • POMD
  • 5
  • Normal melting temperature, K ; Crystal
  • Crystal
  • Liquid
  • Air at 1 atmosphere
  • DTA
  • 1
  • POMD
  • 5
  • Molar heat capacity at constant pressure, J/K/mol ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • Drop calorimetry
  • 1
  • POMD
  • 5
  • Molar enthalpy of vaporization or sublimation, kJ/mol ; Crystal
  • Temperature, K; Crystal
  • Crystal
  • Gas
  • Static calorimetry
  • 1
  • POMD
  • 5
  • Mass density, kg/m3 ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • mass and size of pellet
  • 1
  • RXND
  • 4
  • 1
  • 2
  • 3
  • Specific internal energy of reaction at constant volume, J/g
  • Static bomb calorimetry
  • 1
  • RXND
  • 5
  • 1
  • 2
  • 3
  • Specific internal energy of reaction at constant volume, J/g
  • Static bomb calorimetry
  • 1