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Electric birefringence of poly‐ L ‐lysine hydrobromide in methanol–water mixtures and helix–coil transition induced by high electric fields
Author(s) -
Kikuchi Kazuo,
Yoshioka Koshiro
Publication year - 1973
Publication title -
biopolymers
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.556
H-Index - 125
eISSN - 1097-0282
pISSN - 0006-3525
DOI - 10.1002/bip.1973.360121204
Subject(s) - chemistry , electric field , birefringence , electromagnetic coil , field strength , flow birefringence , dipole , helix (gastropod) , anisotropy , polarization (electrochemistry) , molecular physics , nuclear magnetic resonance , analytical chemistry (journal) , magnetic field , optics , physics , organic chemistry , quantum mechanics , snail , biology , ecology
The electric birefringence of poly‐ L ‐lysine hydrobromide in methanol–water mixtures has been measured at 25 °C over a wide range of field strengths by use of the rectangular pulse technique. An abrupt change in the specific Kerr constant was observed between 87 and 90 vol % methanol, corresponding to the solvent‐induced helix–coil transition. The specific Kerr constant increased rapidly with dilution in the random coil form, and more slowly in the helical conformation. The field strength dependence of the bire fringence at various concentrations, for both the helical and coil conformations, can be described by a common orientation function, which resembles the theoretical one for the case of permanent dipole moment orientation. This is interpreted in terms of the saturation of ion–atmosphere polarization. The optical anisotropy for the helical conformation was much larger than that for the coil form. Anomalous birefringence signals were observed above a critical field strength (about 5 kV/cm) in 90 vol % methanol. The birefringence passed through a maximum and began to decrease slowly before the pulse terminated, reaching a steady‐state value. This steady‐state value was closer to that of the coil in the coil in the limit of very high fields. The results indicate that a transition from the charged helix to the charged coil is induced by high electric fields in the transition region. This effect can be explained on the basis of the polarization mechanism proposed by Neumann and Katchalasky.