Category:NMR: Difference between revisions
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Many nuclei have an inherent, non-zero spin '''I''' and therefore a magnetic dipole moment '''μ''', conventionally along the z-axis: | |||
:<math> | |||
\mu_z = \gamma \textbf{I}_z | |||
</math> | |||
In the absence of a magnetic field, these are degenerate states. When an external magnetic field '''B'''<sub>ext</sub> is applied, the energy difference between two states is given by the following equation: | |||
:<math> | |||
\Delta E = \gamma \hbar \textbf{B}_{ext} | |||
</math> | |||
Conventionally, the z-axis is chosen for the direction of '''B'''<sub>ext</sub>. Along this axis, '''μ''' aligned with '''B'''<sub>ext</sub> will be slightly more energetically favorable and so populated than '''μ''' opposed to '''B'''<sub>ext</sub>. This is only signficant in the presence of strong magnetic fields. | |||
In the presence of '''B'''<sub>ext</sub>, '''μ''' precesses at its Larmor frequency ''ω''<sub>L</sub>, determined by the strength of the magnetic field and the nucleus' gyromagnetic ratio γ: | |||
:<math> | |||
\omega_L = \gamma \textbf{B} | |||
</math> | |||
A weak, oscillating magnetic field applied perpendicular (i.e. in the ''transverse frame'') to '''B'''<sub>ext</sub> (''reference frame''), e.g. using a radio-frequnecy (RF) pulse at frequnecy ω<sub>rf</sub>, can causes '''μ''' to oscillate with the RF. If ω<sub>rf</sub> is similar to ω<sub>L</sub>, then resonance occurs, hence nuclear magnetic resonance (NMR). '''μ''' flips from the reference to the transverse frame and the relaxation of '''μ''' back to the reference frame creates a signal that is measured in NMR. | |||
== How to == | == How to == | ||
*Chemical shift tensors: {{TAG|LCHIMAG}}. | *Chemical shift tensors: {{TAG|LCHIMAG}}. | ||
Revision as of 09:50, 24 February 2025
Many nuclei have an inherent, non-zero spin I and therefore a magnetic dipole moment μ, conventionally along the z-axis:
In the absence of a magnetic field, these are degenerate states. When an external magnetic field Bext is applied, the energy difference between two states is given by the following equation:
Conventionally, the z-axis is chosen for the direction of Bext. Along this axis, μ aligned with Bext will be slightly more energetically favorable and so populated than μ opposed to Bext. This is only signficant in the presence of strong magnetic fields.
In the presence of Bext, μ precesses at its Larmor frequency ωL, determined by the strength of the magnetic field and the nucleus' gyromagnetic ratio γ:
A weak, oscillating magnetic field applied perpendicular (i.e. in the transverse frame) to Bext (reference frame), e.g. using a radio-frequnecy (RF) pulse at frequnecy ωrf, can causes μ to oscillate with the RF. If ωrf is similar to ωL, then resonance occurs, hence nuclear magnetic resonance (NMR). μ flips from the reference to the transverse frame and the relaxation of μ back to the reference frame creates a signal that is measured in NMR.
How to
- Chemical shift tensors: LCHIMAG.
- Hyperfine tensors: LHYPERFINE.
- Electric field gradient tensors: Electric Field Gradient. The main tags are:
Subcategories
This category has the following 3 subcategories, out of 3 total.
Pages in category "NMR"
The following 13 pages are in this category, out of 13 total.