Solvation dynamics and rotational
relaxation of coumarin
480 in aqueous micelles of cationic gemini surfactants with diethyl
ether (EE) spacer group (
m
–EE–
m
) and tails with varying tail lengths (
m
= 12, 14, and 16) have been studied. Studies have been carried out
by measuring UV–visible absorption, steady-state fluorescence
and fluorescence anisotropy, time-resolved fluorescence and fluorescence
anisotropy,
1
H NMR spectroscopy, and dynamic light scattering.
Effects of hydrocarbon tail length and hydrophilicity of spacer group
on solvation dynamics and rotational relaxation processes at inner
side of the Stern layer of micelles have been studied. With increasing
hydrophobicity of tails of surfactants, water molecules in the Stern
layer become progressively more rigid, resulting in a decrease in
the rate of solvation process with slow solvation as a major component.
With increasing hydrophilicity of the spacer group of gemini surfactant,
the extent of free water molecules is decreased, thereby making the
duration of the solvation process longer. Solvation times in the micelles
of gemini surfactants with hydrophilic spacer are almost 4 times longer
compared to those in the micelles of their conventional counterpart.
Rotational relaxation time increases with increasing tail length of
surfactant as a result of increasing microviscosity of micelles with
fast relaxation as a major component. With increasing hydrophilicity
of the spacer group, the anisotropy decay becomes slower due to the
formation of more compact micelles. Rotational relaxation in gemini
micelles is also slower compared to that in their conventional counterpart.
The anisotropy decay is found to be biexponential with lateral diffusion
of the probe along the surface of the micelle as a slow component.
Rotational motion of micelle as a whole is a very slow process, and
the motion becomes further slower with increasing size of the micelle.
The time constants for wobbling motion and lateral diffusion of the
probe become longer with increasing microviscosity of micelles.
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