Ultrafast Energy Migration Pathways in Self-Assembled Phospholipids Interacting with Confined Water

Ultrafast Energy Migration Pathways in Self-Assembled Phospholipids Interacting with Confined Water

Phospholipids self-assembled into reverse micelles in benzene are introduced as a new model system to study elementary processes relevant for energy transport in hydrated biological membranes. Femtosecond vibrational spectroscopy gives insight into the dynamics of the antisymmetric phosphate stretch...

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Bibliographic Details
Published in:The journal of physical chemistry. A, Molecules, spectroscopy, kinetics, environment, & general theory Vol. 115; no. 43; pp. 11952 - 11959
Main Authors: Levinger, Nancy E, Costard, Rene, Nibbering, Erik T. J, Elsaesser, Thomas
Format: Journal Article
Language:English
Published: United States American Chemical Society 03-11-2011
Subjects:
A: Kinetics, Spectroscopy
Dynamical systems
Dynamics
Energy Transfer
Femtosecond
Micelles
Molecular Structure
Oscillators
Phospholipids
Phospholipids - chemistry
Spectroscopy
Thermodynamics
Transport
Vibration
Water - chemistry
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Summary:Phospholipids self-assembled into reverse micelles in benzene are introduced as a new model system to study elementary processes relevant for energy transport in hydrated biological membranes. Femtosecond vibrational spectroscopy gives insight into the dynamics of the antisymmetric phosphate stretching vibration νAS(PO2)−, a sensitive probe of local phosphate–water interactions and energy transport. The decay of the νAS(PO2)− mode with a 300-fs lifetime transfers excess energy to a subgroup of phospholipid low-frequency modes, followed by redistribution among phospholipid vibrations within a few picoseconds. The latter relaxation is accelerated by adding a confined water pool, an efficient heat sink in which the excess energy induces weakening or breaking of water–water and water–phospholipid hydrogen bonds. In parallel to vibrational relaxation, resonant energy transfer between νAS(PO2)− oscillators delocalizes the initial excitation.
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ISSN:1089-5639
1520-5215
DOI:10.1021/jp206099a