Study on an estimation of the contributed energy to the transfer free energies of complex ions. Part I. [Fe(CN)(2n)(phen)((3-n))]((2-2n)+) from waterto a water-ethanol mixed solvent
T. Tarui, Study on an estimation of the contributed energy to the transfer free energies of complex ions. Part I. [Fe(CN)(2n)(phen)((3-n))]((2-2n)+) from waterto a water-ethanol mixed solvent, B CHEM S J, 73(11), 2000, pp. 2481-2486
The solubilities of [Fe(phen)(3)](ClO4)(2).H2O, [Fe(CN)(2)(phen)(2)].0.5H(2
)O, [Fe(phen)(3)] [Fe(CN)(4)phen]. 8H(2)O, and [Fe(phen)(3)](2)[Fe(CN)(6)].
3.5H(2)O in ethanol-water mixed solvents were measured at 25.0 +/-0.1 degre
esC, and the transfer free energy of each complex ion from water to water-e
thanol mixed solvent was calculated. From the obtained data, the transfer f
ree energies were split into contributions from 1,10-phenanthroline-solvent
, cyano ligand-solvent interaction energies, and electrostatic energies. Th
e ratio of the contributed energy from 1,10-phenanthroline vs. transfer fre
e energy of free (noncoordinated) 1,10-phenanthroline is almost constant at
about 0.6-0.7 over the whole mole-fraction range. There is thus a possibil
ity to estimate the contributed energy from the transfer free energy of the
free ligand in the future. On the other hand, the contributed energy from
the cyano ligand can not be obtained by multiplying a certain coefficient t
o the transfer free energy of the free cyanide ion. The contributed energy
from electrostatic energy changes in a somewhat different manner, as expect
ed by the Born equation. However, the estimated transfer free energy as the
sum of each contributed energy obtained by a least-squares method is in fa
ir agreement with the observed transfer free energy of each complex ion. It
has been confirmed that the proposed conception of the contributed energy
to the transfer free energy is a useful means to predict the unknown transf
er free energy of complex ions.