COUPLING CONSTANT

The signal splitting in ¹H-NMR spectra is usually small, ranging from fractions of a Hz to as much as 18 Hz, and is designated as J (referred to the coupling constant).

Coupling Constants (J)
        J  is the distance between peaks in a splitting signal
        the magnitude of J is
                  - dependent only on fields that are caused by magnetic atoms within a molecule but
                  - independent of the external field strength (B₀)

The most common patterns that have been seen are doublet and triplet.

n = 1	n = 2

First-Order and Second-Order spectra

 Spectra that can be interpreted by using n+1 rule are said to be first-order spectra. In first-order spectra, the difference in chemical shifts (in Hz) between 2 groups of protons is large. When Dn/J  is large and we see first-order splitting, the system is said to be weakly coupled.

 In some spectra, using the n+1 rule is not enough, therefore, such advanced analysis may be required for interpreting spectra. These spectra are said to be second-order spectra. In second-order spectra, the difference in chemical shifts between 2 groups of protons is similar in magnitude to the J. When Dn/J  is large and we see second-order splitting, the system is said to be strongly coupled.

Example of first-order spetra

        1. The ethyl acetate spectrum displays the typical quartet and triplet of a substituted ethyl group.

        2. The spectrum of 1,3-dichloropropane demonstrates the triplet (B) and the quintet (A).

Example of second-order spetra

If a given nucleus is spin-coupled to two or more sets of neighboring nuclei by different J values, the n+1 rule does not predict the entire splitting pattern. The spectra may be complicated due to the strong coupling.

These are some examples of more complicated spectra that can be 2^nd order spectra.

Magnitude of Some Typical Coupling Constants