Nuclear Overhauser effect/Advanced: Difference between revisions

Revision as of 02:59, 12 October 2008

Main Article

Discussion

Related Articles ^[?]

Bibliography ^[?]

External Links ^[?]

Citable Version ^[?]

Advanced ^[?]

An advanced level version of Nuclear Overhauser effect.

{Def|Nuclear Overhauser effect}

The Noe enhancement is quantitatively defined as

\eta ={\frac {S_{z}-S_{z,equil}}{S_{z,equil}}}\qquad Eq.1

For a pair of nonidentical spins I and S, :

{\frac {d<I_{z}>}{dt}}=-\rho _{I}(<I_{z}>-<I_{z,equil}>)-\sigma (<S_{z}>-<S_{z,equil}>)\qquad Eq.2

{\frac {d<S_{z}>}{dt}}=-\rho _{S}(<S_{z}>-<S_{z,equil}>)-\sigma (<I_{z}>-<I_{z,equil}>)\qquad Eq.3

\sigma

is called the cross relaxation rate and is responsible for the Nuclear overhauser effect.

\rho _{I}={\frac {\gamma _{I}^{2}\gamma _{S}^{2}\hbar ^{2}}{10r^{6}}}(J(w_{I}-w_{S})+3J(w_{I})+6J(w_{I}+w_{S}))\qquad Eq.4

\sigma ={\frac {\gamma _{I}^{2}\gamma _{S}^{2}\hbar ^{2}}{10r^{6}}}(-J(w_{I}-w_{S})+6J(w_{I}+w_{S})))\qquad Eq.5

{\frac {1}{T_{2}}}={\frac {\gamma ^{2}\gamma _{S}^{2}\hbar ^{2}}{20r^{6}}}(4J(0)+J(w_{I}-w_{S})+3J(w_{I})+6J(w_{I}+w_{S})+6J(w_{S}))\qquad Eq.6

In the steady state ${\frac {d<S_{z}>}{dt}}=0$ , when the resonance frequency of spin I is irradiated , $<I_{z}>=0$ , therefore:

(<S_{z}>-<S_{z,equil}>)={\frac {\sigma }{\rho _{S}}}(<I_{z,equil}>)(fromEq.3)

Therefore,

\eta ={\frac {<S_{z}>-<S_{z,equil}>}{<S_{z,equil}>}}={\frac {\sigma }{\rho _{S}}}{\frac {\gamma _{I}}{\gamma _{S}}}\qquad Eq.7

This indicates that considerable enhancement in the intensity of the S signal can be obtained by irradiation at the frequency of the I spin, provided that ${\frac {\gamma _{I}}{\gamma _{S}}}>1$ , because ${\frac {\sigma }{\rho _{S}}}\rightarrow 1/2$ when $w\tau _{c}<<1$ . However, when $w\tau _{c}>>1$ , ${\frac {\sigma }{\rho _{S}}}\rightarrow -1$ and negative Noe enhancements are obtained.
The sign of $\eta$ changes from positive to negative when $w\tau _{c}$ is close to one and under such conditions the Noe effect may not be observable. This happens for rigid molecules with relative molecular mass about 500 at room temperature e.g. many hexapeptides.

@@ Line 3: / Line 3: @@
 The Noe enhancement is quantitatively defined as
-: <math> \eta = \frac{S_z - S_{z,equil}}{S_{z,equil}}             Eq. 1 </math>
+: <math> \eta = \frac{S_z - S_{z,equil}}{S_{z,equil}}             \qquad Eq. 1 </math>
 For a pair of nonidentical spins I and S, :
-: <math> \frac{d<I_z>}{dt} = -\rho_I (<I_z> - <I_{z,equil}>) - \sigma (<S_z> - <S_{z,equil}>)   Eq. 2</math>
+: <math> \frac{d<I_z>}{dt} = -\rho_I (<I_z> - <I_{z,equil}>) - \sigma (<S_z> - <S_{z,equil}>)   \qquad Eq. 2</math>
-: <math> \frac{d<S_z>}{dt} = -\rho_S (<S_z> - <S_{z,equil}>) - \sigma (<I_z> - <I_{z,equil}>) Eq. 3 </math>
+: <math> \frac{d<S_z>}{dt} = -\rho_S (<S_z> - <S_{z,equil}>) - \sigma (<I_z> - <I_{z,equil}>) \qquad Eq. 3 </math>
 : <math> \sigma </math> is called the cross relaxation rate and is responsible for the Nuclear overhauser effect.
-: <math> \rho_I = \frac{\gamma_I^2\gamma_S^2\hbar^2}{10 r^6 } ( J(w_I-w_S) + 3J(w_I) + 6 J(w_I + w_S) ) Eq. 4 </math>
+: <math> \rho_I = \frac{\gamma_I^2\gamma_S^2\hbar^2}{10 r^6 } ( J(w_I-w_S) + 3J(w_I) + 6 J(w_I + w_S) ) \qquad Eq. 4 </math>
-: <math> \sigma = \frac{\gamma_I^2\gamma_S^2\hbar^2}{10 r^6 } ( -J(w_I-w_S) +  6 J(w_I + w_S) )) Eq. 5 </math>
+: <math> \sigma = \frac{\gamma_I^2\gamma_S^2\hbar^2}{10 r^6 } ( -J(w_I-w_S) +  6 J(w_I + w_S) )) \qquad Eq. 5 </math>
-: <math> \frac{1}{T_2} = \frac{\gamma^2\gamma_S^2\hbar^2}{20 r^6 } ( 4J(0) + J(w_I - w_S) + 3J(w_I) + 6 J(w_I + w_S) + 6 J(w_S) ) Eq. 6 </math>
+: <math> \frac{1}{T_2} = \frac{\gamma^2\gamma_S^2\hbar^2}{20 r^6 } ( 4J(0) + J(w_I - w_S) + 3J(w_I) + 6 J(w_I + w_S) + 6 J(w_S) ) \qquad Eq. 6 </math>
-In the steady state <math> \frac{d<S_z>}{dt} = 0 </math>, when the resonance frequency of spin I is irradiated , <I_z> = 0, therefore:
+In the steady state <math> \frac{d<S_z>}{dt} = 0 </math>, when the resonance frequency of spin I is irradiated , <math> <I_z> = 0</math>, therefore:
 : <math> (<S_z> - <S_{z,equil}>)=  \frac{\sigma}{\rho_S} (<I_{z,equil}>)  (from Eq. 3) </math>
 Therefore,
-: <math>\eta = \frac{<S_z> - <S_{z,equil}>}{<S_{z,equil}>} = \frac{\sigma}{\rho_S} \frac{\gamma_I}{\gamma_S} Eq. 7 </math>
+: <math>\eta = \frac{<S_z> - <S_{z,equil}>}{<S_{z,equil}>} = \frac{\sigma}{\rho_S} \frac{\gamma_I}{\gamma_S} \qquad Eq. 7 </math>
 This indicates that considerable enhancement in the intensity of the S signal can be obtained by irradiation at the frequency of the I spin, provided that <math> \frac{\gamma_I}{\gamma_S} > 1 </math>, because <math> \frac{\sigma}{\rho_S} \rightarrow 1/2 </math> when <math> w\tau_c << 1 </math>.
 However, when <math> w\tau_c >> 1 </math>, <math> \frac{\sigma}{\rho_S} \rightarrow -1 </math> and negative Noe enhancements are obtained.
 <br/>
 The sign of <math> \eta </math> changes from positive to negative when <math> w\tau_c </math> is close to one and under such conditions the Noe effect may not be observable.  This happens for rigid molecules with relative molecular mass about 500 at room temperature e.g. many hexapeptides.

Nuclear Overhauser effect/Advanced: Difference between revisions

Revision as of 02:59, 12 October 2008

Navigation menu

Search