https://sagacioushours.org.uk/wiki/index.php?action=history&feed=atom&title=Talk%3AMod%3AHunt_Research_Group%2FlegendreTalk:Mod:Hunt Research Group/legendre - Revision history2026-05-27T11:47:12ZRevision history for this page on the wikiMediaWiki 1.34.2https://sagacioushours.org.uk/wiki/index.php?title=Talk:Mod:Hunt_Research_Group/legendre&diff=2433&oldid=prevWikiadmin: Created page with "'''Investigation of reorientational dynamics in liquids using the Legendre reorientational time correlation functions.''' <br> The rotational motions in liquids are very sens..."2020-11-25T21:23:17Z<p>Created page with "'''Investigation of reorientational dynamics in liquids using the Legendre reorientational time correlation functions.''' <br> The rotational motions in liquids are very sens..."</p>
<p><b>New page</b></p><div>'''Investigation of reorientational dynamics in liquids using the Legendre reorientational time correlation functions.''' <br><br />
<br />
The rotational motions in liquids are very sensitive on the local environment around the molecules and depend very much on the intermolecular interactions <br><br />
between each rotating molecule and its surrounding molecules. Very often, in order to investigate the rotational dynamics in molecular liquids <br> and to provide a quantitative description of these relaxation processes we use the so-called “Legendre Reorientational Time Correlation functions”.<br><br />
In general, the reorientational dynamics for specified intramolecular vectors are investigated by means of the Legendre reorientational tcfs:<br><br />
<br />
[[Image:exisosi1.JPG]] (1) <br><br />
In this equation u is a unit vector along a specified direction inside a molecule and P is a Legendre polynomial, e.g.: <br><br />
<br><br />
[[Image:exisosi2.JPG]] <br><br />
<br><br />
The corresponding reorientational times are defined as follows: <br><br />
<br />
[[Image:exisosi3.JPG]] (2) <br> <br />
<br><br />
These quantities can be extracted by molecular dynamics simulations, as well as by experimental techniques such as infrared absorption, <br><br />
dielectric relaxation, Raman and Rayleigh scattering, NMR relaxation as well as time resolved spectroscopy [1].<br><br />
When investigating reorientational dynamics in liquids we have to take into account at least two extreme cases, <br><br />
described by the corresponding theoretical models. <br><br />
The first one is the Debye diffusion model [2], describing the molecular reorientation as an “infinitely small”<br><br />
step angular random walk (angular Brownian motion).This model is often used to describe reorientation mechanisms in “liquid-like” dense fluids. <br><br />
The other one, which is frequently applied to analyze reorientational dynamics in low-density “gas-like” fluids, <br><br />
is called the inertial rotation or free rotor model, according to which the molecules can rotate freely during <br><br />
a period perturbed by molecular collisions. <br><br />
In the case of diffusive (Debye) reorientational dynamics, the Legendre reorientational correlation functions exhibit <br> single exponential time decay. The time constant of this exponential decay is the Legendre reorientational correlation time: <br><br />
[[Image:exisosi4.JPG]] (3) <br><br />
<br><br />
In this case the first, second and third order Legendre reorientational times are related through the equations: <br><br />
[[Image:exisosi5.JPG]] (4) <br><br />
<br><br />
Furthermore, according to the diffusive model the Legendre reorientational times are related to the rotational diffusion <br> coefficient through the equation: <br><br />
[[Image:exisosi6.JPG]] (5) <br><br />
<br><br />
Other theoretical models like e.g. the extended J-diffusion model [3] have been also proposed in the literature <br><br />
to interpret the reorientational dynamic behaviour of several molecular liquid systems.<br><br />
In the case of strongly hydrogen bonded molecules (e.g. liquid water) the reorientational dynamics cannot <br><br />
be interpreted by using a diffusive Debye model and a newly presented Extended Jump model has been recently proposed [4]. <br> According to this model, water reorientation proceeds mainly via large angular jumps occurring during an exchange of H-bond <br> acceptors plus a slower, less important, component related to the H-bond axis diffusive reorientation. <br><br />
<br />
'''Effect of the local HB network on reorientational dynamics.''' <br><br />
<br />
In order to depict more clearly the significance of the strength of the intermolecular interactions and of the <br><br />
local structural network on the reorientational dynamics in hydrogen bonded fluids, we performed an additional analysis <br><br />
of reorientational dynamics, where we calculated the Legendre reorientational tcfs as a function of the hydrogen bonds per <br> molecule. These functions can be defined as follows [5]: <br><br />
[[Image:exisosi7.JPG]]... etc (6) <br><br />
As previously, the index l defines the order of the Legendre polynomial, whereas the index n defines the <br><br />
instantaneous number of hydrogen bonds which forms a molecule at each time t. <br><br />
The function [[Image:exisosi8.JPG]] is defined as follows: <br><br />
[[Image:exisosi9.JPG]] , if a molecule forms n hydrogen bonds at time t. <br><br />
[[Image:exisosi10.JPG]] , otherwise. <br><br />
The corresponding reorientational times are defined as: <br><br />
[[Image:exisosi11.JPG]] (7) <br><br />
<br />
'''References''' <br><br />
1)(a) ''Spectroscopy and Relaxation of Molecular Liquids''; Steele, D., Yarwood, J., Eds.; Elsevier: Amsterdam, '''1991''' <br><br />
(b) ''Vibrational Spectra and Structure''; Durig, J. R., Ed.; Elsevier: Amsterdam, '''1977'''; Vol. 6 <br><br />
(c) Steele, W. A. ''Adv. Chem. Phys.'' '''1977''', 34, 1<br />
2) Debye, P. ''Polar Molecules''; Dover: New York, '''1945'''<br />
3) Gordon, R. G. ''J. Chem. Phys.'' '''1966''', 44, 1830<br />
4) Laage, D.; Hynes,J. T. ''J. Phys. Chem. B'' '''2008''', 112, 14230<br />
5) Skarmoutsos, I.; Guardia, E. ''J. Phys. Chem. B'' '''2009''', 113, 8898</div>Wikiadmin