Almost all two-liquid phase bioprocesses are characterized by the presence
of surface active materials (biosurfactants), which significantly influence
the interaction between the phases. In order to predict mass transfer rate
s during cultivations of Pseudomonas oleovorans biosurfactant was isolated
from the biosuspension and added in defined amounts to n-octane/water model
-dispersions. Effects of biosurfactant concentration on interfacial tension
, mean Sauter-diameter, drop size distribution, dispersion stability and li
quid-liquid mass transfer coefficients were studied. A comparison was made
between calculated solvent transfer rates (STR) and measured solvent uptake
rates (SUR) of P. oleovorans cultures.
With increasing interfacial surfactant concentration interfacial tension an
d mean Sauter-diameter decreased until a minimum for both, interfacial tens
ion and mean Sauter-diameter, were reached. Interfacial tension measurement
s indicate that these minima have to be attributed to a maximum monomolecul
ar surfactant concentration and the formation of polymolecular adsorption l
ayers. Drop size distributions showed that, coalescence and droplet break-u
p disappear because droplets are stabilized by the biosurfactant adsorption
layers at the interface. Mass transfer regime shifted from forced convecti
on and surface renewal to diffusion. Comparison of solvent uptake rates (SU
R) and solvent transfer rates (STR) showed that n-octane transfer usually w
ill not be limiting P. oleovorans cultures, however, can become dominant in
cultures where solvents with very low miscibilities like n-decane are used
.