One of the characteristic features of rotation–vibration dynamics is the existence of a variety of energy bands which result from organization of energy levels into bands depending on control parameters. Symmetry and topology aspects of the organization of energy bands and generic modifications of this structure for molecular systems with symmetry are discussed in a way parallel to the description of topological quantum transitions extensively studied in condensed matter physics. A special class of axially symmetric molecular systems is analyzed. It is shown that only a finite number of different band structures are possible for rotation–vibration problem with a finite number of vibrational states in the case of continuous axial symmetry, whereas for problems with finite group symmetry an arbitrary large number of different band structures are formally allowed.
%0 Journal Article
%1 iwai2014topological
%A Iwai, T.
%A Zhilinskii, B.
%D 2014
%I Springer Berlin Heidelberg
%J Theoretical Chemistry Accounts
%K mechanics physics quantum rotational spectroscopy symmetry unread vibration
%N 7
%R 10.1007/s00214-014-1501-x
%T Topological phase transitions in the vibration–rotation dynamics of an isolated molecule
%U http://dx.doi.org/10.1007/s00214-014-1501-x
%V 133
%X One of the characteristic features of rotation–vibration dynamics is the existence of a variety of energy bands which result from organization of energy levels into bands depending on control parameters. Symmetry and topology aspects of the organization of energy bands and generic modifications of this structure for molecular systems with symmetry are discussed in a way parallel to the description of topological quantum transitions extensively studied in condensed matter physics. A special class of axially symmetric molecular systems is analyzed. It is shown that only a finite number of different band structures are possible for rotation–vibration problem with a finite number of vibrational states in the case of continuous axial symmetry, whereas for problems with finite group symmetry an arbitrary large number of different band structures are formally allowed.
@article{iwai2014topological,
abstract = {One of the characteristic features of rotation–vibration dynamics is the existence of a variety of energy bands which result from organization of energy levels into bands depending on control parameters. Symmetry and topology aspects of the organization of energy bands and generic modifications of this structure for molecular systems with symmetry are discussed in a way parallel to the description of topological quantum transitions extensively studied in condensed matter physics. A special class of axially symmetric molecular systems is analyzed. It is shown that only a finite number of different band structures are possible for rotation–vibration problem with a finite number of vibrational states in the case of continuous axial symmetry, whereas for problems with finite group symmetry an arbitrary large number of different band structures are formally allowed.},
added-at = {2014-06-29T16:15:52.000+0200},
author = {Iwai, T. and Zhilinskii, B.},
biburl = {https://www.bibsonomy.org/bibtex/2184cddaf48a4113f9060fc0b43b1e15f/drmatusek},
doi = {10.1007/s00214-014-1501-x},
eid = {1501},
interhash = {8e63706efff4910e8cdc134338d2220d},
intrahash = {184cddaf48a4113f9060fc0b43b1e15f},
issn = {1432-881X},
journal = {Theoretical Chemistry Accounts},
keywords = {mechanics physics quantum rotational spectroscopy symmetry unread vibration},
language = {English},
month = may,
number = 7,
publisher = {Springer Berlin Heidelberg},
timestamp = {2014-06-29T16:15:52.000+0200},
title = {Topological phase transitions in the vibration–rotation dynamics of an isolated molecule},
url = {http://dx.doi.org/10.1007/s00214-014-1501-x},
volume = 133,
year = 2014
}