Pressure Induced Topological Phase Transitions in Membranes

D. A. Wilkinson; D. M. Anderson; E. Shyamsunder; E. Shyamsunder; G. L. Kirk; G. Lindblom; J. Charvolin; J. Stamatoff; K. Chen; K. Larsson; M. W. Tate; O. Narayan; P. A. Winsor; P. T. C. So; P. T. T. Wong; P. Yeager; R. E. Goldstein; S. M. Gruner; S. T. Hyde; S. Utoh; Shyamsunder Erramilli; Sol M. Gruner; V. Luzzati; W. Helfrich

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Pressure Induced Topological Phase Transitions in Membranes

Authors: D. A. Wilkinson
D. M. Anderson
E. Shyamsunder
E. Shyamsunder
G. L. Kirk
G. Lindblom
J. Charvolin
J. Stamatoff
K. Chen
K. Larsson
M. W. Tate
O. Narayan
P. A. Winsor
P. T. C. So
P. T. T. Wong
P. Yeager
R. E. Goldstein
S. M. Gruner
S. T. Hyde
S. Utoh
Shyamsunder Erramilli
Sol M. Gruner
V. Luzzati
W. Helfrich
Publication date: 4 October 1992
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Some highly unusual features of a lipid-water liquid crystal are revealed by high pressure x-ray diffraction, light scattering and dilatometric studies of the lamellar (bilayer

L_{\alpha}

) to nonlamellar inverse hexagonal (

H_{II}

) phase transition. (i) The size of the unit cell of the

H_{II}

phase increases with increasing pressure. (ii) The transition volume,

\Delta V_{bh}

, decreases and appears to vanish as the pressure is increased. (iii) The intensity of scattered light increases as

\Delta V_{bh}

decreases. Data are presented which suggest that this increase is due to the formation of an intermediate cubic phase, as predicted by recent theoretical suggestions of the underlying universal phase sequence.Comment: 12 pages, typed using REVTEX 2.

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