https://doi.org/10.1007/s100510050798
Nucleation-and-growth problem in model lipid membranes undergoing subgel phase transitions is a problem of time scale
Department of Theoretical Physics,
Institute of Mathematics and Physics,
University of Technology and Agriculture,
85-796 Bydgoszcz, Al. Kaliskiego 7, Poland
Corresponding author: a agad@atr.bydgoszcz.pl
Received:
30
November
1998
Published online: 15 June 1999
In this Rapid Note, we show that the problem of growth of molecular superlattice in a fully hydrated dipalmitoylphosphatidylcholine (DPPC) membrane during the gel-to-subgel phase transformation process is a problem of time scale. There are, in fact, two time scales. The first is an "integrated" or, in some sense, stagnant time scale, that reflects the well-known isotropic growth effect in the d-dimensional space, but assigns the problem to be still in a category of Debye relaxation kinetics. The fraction of old (parent) phase does not suit the Paley-Wiener criterion for relaxation functions, and the time behavior is exclusively due to the geometrical characteristics of the kinetic process. The second (multi-instantaneous) time scale, in turn, is recognised to be a "broken" (fractional time derivative) or memory-feeling (dynamic) scale, which carries some very essential physics of the phenomenon under study, and classifies the problem to be of non-Debye (viz., stretched exponential) nature. It may, in principle, contain all the important effects, like small scale coexistence, presence of collisions between domains, with possible annihilation and creation of domain boundaries, and/or a headgroup packing, hydration against lipid mobility behavior, and finally, a multitude of quasi-crystalline states. It turns out, that within the range of validity of the dynamic scale approximation proposed, the criterion for relaxation functions is very well fulfilled.
PACS: 82.60.Nh – Thermodynamics of nucleation / 64.60.-i – General studies of phase transitions / 64.70.-p – Specific phase transitions
© EDP Sciences, Società Italiana di Fisica, Springer-Verlag, 1999