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5.2: The Origin of the NMR Signal

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    106316
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    The Magnetic Moment

    Nuclear magnetic resonance spectroscopy is an incredibly powerful tool for organic chemists because it allows us to analyze the connectivity of carbon and hydrogen atoms in molecules. The basis for NMR is the observation that many atomic nuclei generate their own magnetic field, or magnetic moment, as they spin about their axes. Not all nuclei have a magnetic moment. Fortunately for organic chemists, though, hydrogen (\(^1H\)), the \(^{13}C\) isotope of carbon, the \(^{19}F\) isotope of fluorine, and the \(^{31}P\) isotope of phosphorus all have magnetic moments and therefore can be observed by NMR – they are, in other words, NMR-active. Other nuclei - such as the common \(^{12}C\) and \(^{16}O\) isotopes of carbon and oxygen - do not have magnetic moments, and cannot be directly observed by NMR. Still other nuclei such as the hydrogen isotope deuterium (\(^2H\)) and nitrogen (\(^{14}N\)) have magnetic moments and are NMR-active, but the nature of their magnetic moments is such that analysis of these nuclei by NMR is more complex.

    In practice it is \(^1H\) and \(^{13}C\) nuclei that are most commonly observed by NMR spectroscopy, and it is on those techniques that we will focus in this chapter, beginning with \(^1H\)-NMR. The terms ‘proton’ and ‘hydrogen’ are used interchangeably when discussing because the \(^1H\) nucleus is just a single proton.

    Table 5.2.1 : Some examples of magnetic and nonmagnetic nuclei relevant to biological organic chemistry.
    Magnetic Nuclei Nonmagnetic Nuclei

    \(^1H\)

    \(^{12}C\)

    \(^2H\)

    \(^{16}O\)

    \(^{13}C\)

    \(^{32}S\)

    \(^{14}N\)

    \(^{19}F\)

    \(^31P\)

    Spin States and the Magnetic Transition

    When a sample of an organic compound is sitting in a flask on a laboratory bench, the magnetic moments of all of its protons are randomly oriented. However, when the same sample is placed within the field of a very strong superconducting magnet (this field is referred to by NMR spectroscopists as the applied field, abbreviated \(B_0\) ) each proton will assume one of two possible quantum spin states. In the +½ spin state, the proton's magnetic moment is aligned with the direction of \(B_0\), while in the -½ spin state it is aligned opposed to the direction of \(B_0\).

    Left: two protons pointing in different directions. Text: no external magnetic field; movements are randomly oriented. Right: Strong external magnetic field. Protons align; one in minus 1/2 spin state and one in plus 1/2 spin state. Text: movements align with or against external field.

    +½ spin state is slightly lower in energy than the -½ state, and the energy gap between them, which we will call \(\Delta E\), depends upon the strength of \(B_0\): a stronger applied field results in a larger \(\Delta E\). For a large population of organic molecules in an applied field, slightly more than half of the protons will occupy the lower energy +½ spin state, while slightly less than half will occupy the higher energy -½ spin state. It is this population difference (between the two spin states) that is exploited by NMR, and the difference increases with the strength of the applied magnetic field.

    At this point, we need to look a little more closely at how a proton spins in an applied magnetic field. You may recall playing with spinning tops as a child. When a top slows down a little and the spin axis is no longer completely vertical, it begins to exhibit precessional motion, as the spin axis rotates slowly around the vertical. In the same way, hydrogen atoms spinning in an applied magnetic field also exhibit precessional motion about a vertical axis. It is this axis (which is either parallel or antiparallel to \(B_0\)) that defines the proton’s magnetic moment.

    Diagram of proton spin. Text labels red dashed arrow going up through the proton as axis of precision (defines magnetic dipole). Text labels black circular arrow coming off the proton as axis of spin.

    Watch the first minute or so of this video of spinning tops: look for the precessional motion

    The frequency of precession (also called the Larmour frequency, abbreviated \(\nu _L\)) is simply the number of times per second that the proton precesses in a complete circle. A proton`s precessional frequency increases with the strength of \(B_0\).

    If a proton that is precessing in an applied magnetic field is exposed to electromagnetic radiation of a frequency \(\nu \)that matches its precessional frequency \(\nu _L\), we have a condition called resonance. In the resonance condition, a proton in the lower-energy +½ spin state (aligned with \(B_0\)) will transition (flip) to the higher energy –½ spin state (opposed to \(B_0\)). In doing so, it will absorb radiation at this resonance frequency n - and this frequency corresponds to \(\Delta E\),

    the energy difference between the proton’s two spin states. With the strong magnetic fields generated by the superconducting magnets used in modern NMR instruments, the resonance frequency for protons falls within the radio-wave range, anywhere from 100 MHz to 800 MHz depending on the strength of the magnet.

    Two protons aligned in different energy levels jump to the same higher energy level when exposed to frequency with hv = delta E.

    Think back for a moment to the other two spectroscopic techniques we have learned about: IR and UV-Vis spectroscopy. Recall from section 4.2 that photons of electromagnetic radiation of a given frequency correspond to energy (E) given by \(E = \hbar\nu\), where \(\hbar\)is Plank's constant and n is the frequency in waves per second, or Hz. Recall also from section 4.3 that the energy gap between vibrational states corresponds to the energy associated with infrared radiation, and from section 4.4 that the energy gap between electronic states in conjugated p-bonding systems corresponds to the energy associated with light in the ultraviolet and visible regions of the electromagnetic spectrum. Now, we know that in NMR, the energy gap \(\Delta E\) between the +½ and -½ spin states of an atomic nucleus in a strong magnetic field corresponds to the energy associated with radiation in the radio frequency (Rf) region of the spectrum.

    By detecting the frequency of Rf radiation that is absorbed, we can gain information about the chemical environment of protons in an organic molecule.

    Exercise 5.2.1

    In a general sense, how big is the energy gap for the nuclear spin transition observed in NMR compared to the energy gap for the vibrational transition observed in IR spectroscopy? Much bigger? Much smaller? Slightly bigger or smaller? About the same? How can you tell from the information presented in this section?


    This page titled 5.2: The Origin of the NMR Signal is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Tim Soderberg via source content that was edited to the style and standards of the LibreTexts platform; a detailed edit history is available upon request.