Rotational relaxation: Difference between revisions

Latest revision as of 07:23, 21 October 2016

Rotational relaxation refers to the decay of certain autocorrelation magnitudes related to the orientation of molecules. If a molecule has an orientation along a unit vector ${\mathbf {n} }$ , its autocorrelation will be given by

c_{1}(t)=\langle \mathbf {n} (0)\cdot \mathbf {n} (t)\rangle .

From the time decay, or relaxation, of this function, one may extract a characteristic relaxation time (either from the long-time exponential decay, or from its total integral, see autocorrelation). This magnitude, which is readily computed in a simulation is not directly accessible experimentally, however. Rather, relaxation times of the second spherical harmonic are obtained:

c_{2}(t)=\langle P_{2}(\mathbf {n} (0)\cdot \mathbf {n} (t))\rangle ,

where $P_{2}(x)$ is the second Legendre polynomial.

According to simple rotational diffusion theory, the relaxation time for $c_{1}(t)$ would be given by $\tau _{1}={\frac {1}{2D_{\mathrm {rot} }}}$ , and the relaxation time for $c_{2}(t)$ would be $\tau _{2}={\frac {1}{6D_{\mathrm {rot} }}}$ . Therefore, $\tau _{1}=3\tau _{2}$ . This ratio is actually lower in simulations, and closer to $2$ ; the departure from a value of 3 signals rotation processes "rougher" than what is assumed in simple rotational diffusion (Ref 1).

Water[edit]

Main article Rotational relaxation of water

Often, molecules are more complex geometrically and can not be described by a single orientation. In this case, several vectors should be considered, each with its own autocorrelation. E.g., typical choices for water molecules would be:

symbol	explanation	experimental value, and method
HH	H-H axis	$\tau _{2}=2.0$ ps (H-H dipolar relaxation NMR)
OH	O-H axis	$\tau _{2}=1.95$ ps (¹⁷O-H dipolar relaxation NMR)
$\mu$	dipolar axis	not measurable, but related to bulk dielectric relaxation
$\perp$	normal to the molecule plane	not measurable

References[edit]

David van der Spoel, Paul J. van Maaren, and Herman J. C. Berendsen "A systematic study of water models for molecular simulation: Derivation of water models optimized for use with a reaction field", J. Chem. Phys. 108 10220 (1998)

@@ Line 1: / Line 1: @@
 '''Rotational relaxation''' refers to the decay of certain [[autocorrelation]]
 magnitudes related to the orientation of molecules.
+If a molecule has an orientation along a unit vector <math>{\mathbf n}</math>, its autocorrelation
-If a molecule has an orientation along a unit vector '''n''', its autocorrelation
 will be given by
 :<math>c_1(t)=\langle \mathbf{n}(0)\cdot\mathbf{n}(t) \rangle.</math>
@@ Line 8: / Line 7: @@
 a characteristic relaxation time (either from the long-time exponential decay, or
 from its total integral, see [[autocorrelation]]). This magnitude, which
-is readily computed in a [[simulation]] is not directly accessible experimentally,
+is readily computed in a [[Computer simulation techniques |simulation]] is not directly accessible experimentally,
 however. Rather, relaxation times of the second
 [[spherical harmonics|spherical harmonic]] are obtained:
-:<math>c_1(t)=\langle P_2(  \mathbf{n}(0)\cdot\mathbf{n}(t) ) \rangle,</math>
+:<math>c_2(t)=\langle P_2(  \mathbf{n}(0)\cdot\mathbf{n}(t) ) \rangle,</math>
 where <math>P_2(x)</math> is the second [[Legendre polynomials|Legendre polynomial]].
 According to simple [[rotational diffusion]] theory, the relaxation time
 for <math>c_1(t)</math> would be given by
-<math>\tau_1 = 1/2D_\mathrm{rot}</math>, and the relaxation time for
+<math>\tau_1 = \frac{1}{2D_\mathrm{rot}}</math>, and the relaxation time for
-<math>c_2(t)</math> would be <math>\tau_2 = 1/6D_\mathrm{rot}</math>.
+<math>c_2(t)</math> would be <math>\tau_2 = \frac{1}{6D_\mathrm{rot}}</math>.
 Therefore, <math>\tau_1= 3 \tau_2</math>. This ratio is actually lower in simulations,
 and closer to <math>2</math>; the departure from a value of 3 signals rotation
 processes "rougher" than what is assumed in simple [[rotational diffusion]] (Ref 1).
 ==Water==
+:''Main article [[Rotational relaxation of water]]
 Often, molecules are more complex geometrically and can not be described by a single
 orientation. In this case, several vectors should be considered, each with its own
@@ Line 35: / Line 32: @@
 | HH   || H-H axis  ||  <math>\tau_2=2.0</math>ps  (H-H dipolar relaxation NMR)
 |-
-| OH   || O-H axis  ||  <math>\tau_2=1.95</math>ps (<math>^{17}</math>O-H dipolar relaxation NMR)
+| OH   || O-H axis  ||  <math>\tau_2=1.95</math>ps (<sup>17</sup>O-H dipolar relaxation NMR)
 |-
 | <math>\mu</math> || dipolar axis || not measurable, but related to bulk dielectric relaxation
@@ Line 42: / Line 39: @@
 |-
 |}
+==See also==
+*[[Rotational diffusion]]
+*[[Diffusion]]
+*[[Autocorrelation]]
 ==References==
+#[http://dx.doi.org/10.1063/1.476482 David van der Spoel, Paul J. van Maaren, and Herman J. C. Berendsen "A systematic study of water models for molecular simulation: Derivation of water models optimized for use with a reaction field",  J. Chem. Phys. '''108''' 10220 (1998)]
-*[http://dx.doi.org/10.1063/1.476482 David van der Spoel, Paul J. van Maaren, and Herman J. C. Berendsen "A systematic study of water models for molecular simulation: Derivation of water models optimized for use with a reaction field",  J. Chem. Phys. '''108''' 10220 (1998)]
-==See also==
-*[[rotational diffusion]]
-*[[diffusion]]
-*[[autocorrelation]]
 [[Category: Non-equilibrium thermodynamics]]

Rotational relaxation: Difference between revisions

Latest revision as of 07:23, 21 October 2016

Water[edit]

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Rotational relaxation: Difference between revisions

Latest revision as of 07:23, 21 October 2016

Water[edit]

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References[edit]

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