Thermodynamics Research Center / ThermoML | Journal of Chemical Thermodynamics

Entropy, related thermodynamic properties, and structure of methylisocyanate

Davis, P. S.[Phil S.], Kilpatrick, J. E.[John E.]
J. Chem. Thermodyn. 2013, 58, 134-41
ABSTRACT
The entropy and related thermodynamic properties of methylisocyanate, CH3NCO, have been determined by isothermal calorimetry. The entropy in the ideal gas state at 298.15 K and 1 atmosphere is = 67.96 + 0.15 cal/K*mol. Other thermodynamic properties determined include: the heat capacity from 15 K to 300 K, the temperature of fusion (Tfus = 178.461 + 0.024 K ), the enthalpy of fusion (AHfus = 1781.84 + 3.34 cal/mol ), the enthalpy of vaporization at 298.15 K (AHvap = 6875.7 + 12.9 cal/mol ), and the vapor pressure from fusion to 300 K. Using statistical thermodynamics, the entropy in this same state has been calculated for various assumed structures for methylisocyante which have been proposed based on several spectroscopic and ab initio results. Comparisons between the experimental and calculated entropy have led to the following conclusions concerning historical differences among problematic structural properties: 1.) The CNC/CNO angles can have the paired values of 140/180 degrees or 135/173 degrees respectively. It is not possible to distinguish between the two by this thermodynamic analysis. 2.) The methyl group functions as a free rotor or near free rotor against the NCO rigid frame. The barrier to internal rotation is less than 500 cal/mol. 3.) The CNC vibrational bending frequency is consistent with the more recently observed assignments at 165 cm-1 and 172 cm-1 with some degree of anharmonicity or with a pure harmonic at about 158 cm-1.
Compounds
# Formula Name
1 C2H3NO methyl isocyanate
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
  • 1
  • Triple point temperature, K ; Crystal
  • Crystal
  • Liquid
  • Gas
  • Adiabatic calorimetry
  • 1
  • POMD
  • 1
  • Molar enthalpy of transition or fusion, kJ/mol ; Crystal
  • Crystal
  • Liquid
  • Gas
  • Adiabatic calorimetry
  • 1
  • POMD
  • 1
  • Molar enthalpy of vaporization or sublimation, kJ/mol ; Liquid
  • Temperature, K; Liquid
  • Liquid
  • Gas
  • Static calorimetry
  • 1
  • POMD
  • 1
  • Molar heat capacity at constant pressure, J/K/mol ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • Vacuum adiabatic calorimetry
  • 62
  • POMD
  • 1
  • Molar heat capacity at constant pressure, J/K/mol ; Liquid
  • Temperature, K; Liquid
  • Pressure, kPa; Liquid
  • Liquid
  • Vacuum adiabatic calorimetry
  • 20
  • POMD
  • 1
  • Vapor or sublimation pressure, kPa ; Liquid
  • Temperature, K; Liquid
  • Liquid
  • Gas
  • Closed cell (Static) method
  • 25
  • POMD
  • 1
  • Molar heat capacity at constant pressure, J/K/mol ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • Vacuum adiabatic calorimetry
  • 16
  • POMD
  • 1
  • Molar enthalpy, kJ/mol ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • Vacuum adiabatic calorimetry
  • 16
  • POMD
  • 1
  • Molar entropy, J/K/mol ; Crystal
  • Temperature, K; Crystal
  • Pressure, kPa; Crystal
  • Crystal
  • Vacuum adiabatic calorimetry
  • 16
  • POMD
  • 1
  • Molar heat capacity at constant pressure, J/K/mol ; Liquid
  • Temperature, K; Liquid
  • Pressure, kPa; Liquid
  • Liquid
  • Vacuum adiabatic calorimetry
  • 13
  • POMD
  • 1
  • Molar enthalpy, kJ/mol ; Liquid
  • Temperature, K; Liquid
  • Pressure, kPa; Liquid
  • Liquid
  • Vacuum adiabatic calorimetry
  • 13
  • POMD
  • 1
  • Molar entropy, J/K/mol ; Liquid
  • Temperature, K; Liquid
  • Pressure, kPa; Liquid
  • Liquid
  • Vacuum adiabatic calorimetry
  • 13