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Coupling Constants - NMR Spectroscopy | Organic Chemistry PDF Download

Coupling Constant

When two protons couple to each other, they cause splitting of each other’s peaks. The spacing between the peaks is the same for both protons, and is referred to as the coupling constant or J constant. 

  • This number is always given in hertz (Hz), and is determined by the following formula:
    J Hz = ∆ ppm x instrument frequency
  • ∆ ppm is the difference in ppm of two peaks for a given proton. The instrument frequency is determined by the strength of the magnet.

Coupling Constants - NMR Spectroscopy | Organic Chemistry

  • Figure above shows NMR spectrum of 1,1-dichloroethane, collected in a 30 MHz instrument. This compound has coupling between A (the quartet at 6 ppm) and B (the doublet at 2 ppm).
  • For both A and B, the distance between the peaks is equal. In this example, the spacing between the peaks is 0.2 ppm (for example, the peaks for A are at 6.2, 6.0, 5.8, and 5.6 ppm). This is equal to a J constant of (0.2 ppm • 30 MHz) = 6 Hz. 
  • Since the shifts are given in ppm or parts per million, you should divide by 106 . But since the frequency is in megahertz instead of hertz, you should multiply by 106 . These two factors cancel each other out, making calculations nice and simple.
  • Figure below shows the NMR spectrum of the same compound, but this time collected in a 60 MHz instrument.  
    Coupling Constants - NMR Spectroscopy | Organic Chemistry
  • This time, the peak spacing is 0.1 ppm. This is equal to a J constant of (0.1 ppm • 60 MHz) = 6 Hz, the same as before. This shows that the J constant for any two particular protons will be the same value in hertz, no matter which instrument is used to measure it. 

Important Points on Coupling Constant

  • Coupling Constant is not dependent on strength of the external field.
  • Multiplets with the same coupling constants may come from adjacent groups of protons that split each other.
  • Coupling constant is a constant. It does not change in magnitude with change in instrument frequency.
  • Increase in instrument frequency increases only the chemical shift of the nuclei, which increases the resolution of the spectrum.
  • J can be either positive or negative, but only the absolute value is considered.

Coupling Constants - NMR Spectroscopy | Organic Chemistry

  • The coupling constant provides valuable information about the structure of a compound. Some typical coupling constants are shown here.
     Coupling Constants - NMR Spectroscopy | Organic Chemistry

Types of Coupling Constant

1. Based on the coupling partner:

  • Homonuclear Coupling: Coupling between two nuclei of the same atom.
  • Heteronuclear Coupling: Coupling between two nuclei of different atoms.

2. Based on the number of intervening bonds:

  • One Bond Coupling (1J): Strong coupling, mainly heteronuclear.
  • Two Bond Coupling (2J): Geminal coupling, high in magnitude.
  • Three Bond Coupling (3J): Vicinal coupling, lower in magnitude, but highly significant for analysis.

3. Others: Specific couplings of higher order can be extremely useful

in NMR analysis. 

  • Ex: meta coupling, allylic coupling, W-coupling.

One Bond (1J) Coupling

Adjacent nuclei prefer to be in opposite spin states in the ground state. For a typical C—H bond, two peaks are observed in the 13C spectrum, due to the two shown transitions.

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Some common one-bond coupling constants have been displayed below:

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Two Bond (2J) Coupling

Commonly called as geminal coupling, these are usually smaller in magnitude than 1 bond coupling.

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Some common 2 bond coupling constants:

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Variation in 2J Coupling

Geminal coupling increases in magnitude as the decreases, due to higher electron spin correlation.


Coupling Constants - NMR Spectroscopy | Organic Chemistry

Coupling Constants - NMR Spectroscopy | Organic Chemistry


Three Bond (3J) Coupling

Commonly called vicinal coupling, these usually follow the (n+1) rule in simple aliphatic hydrocarbon chains. Nuclear and electronic spin interactions carry the spin information from one hydrogen to its neighbor.

Coupling Constants - NMR Spectroscopy | Organic Chemistry

As a result, the best overlap occurs when the C—H bonds are at a dihedral angle of 0°. 

Variation in 3J Coupling

The magnitude of vicinal coupling is directly related to the dihedral angle between the C—H bonds in question. The Karplus equation relates dihedral angle to the coupling constant between two vicinal hydrogen nuclei.

Coupling Constants - NMR Spectroscopy | Organic Chemistry 

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Coupling Constant of cis/trans alkenes:

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Coupling Constant of

Cyclohexane systems:

Coupling Constants - NMR Spectroscopy | Organic Chemistry

Coupling Constant of Cyclopropane/Epoxide Systems: 

Jcis > Jtrans (unlike in alkenes)


Coupling Constants - NMR Spectroscopy | Organic Chemistry


Long-Range Coupling

Very rarely, but often significantly, coupling takes place between two atoms separated by four bonds or more (nJ; n≥4). The common systems where this is exhibited are allylic systems, rigid bicyclic systems, and aromatic rings. Since these couplings are observed through a large number of bonds, a highly specific stereochemical arrangement is essential.

Coupling Constants - NMR Spectroscopy | Organic Chemistry


Stereochemical Nonequivalence:

  • Usually, two protons on the same C are equivalent and do not split each other.
  • If the replacement of each of the protons of a —CH2 group with an imaginary “Z” gives stereoisomers, then the protons are non-equivalent and will split each other.

Coupling Constants - NMR Spectroscopy | Organic Chemistry

The document Coupling Constants - NMR Spectroscopy | Organic Chemistry is a part of the Chemistry Course Organic Chemistry.
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FAQs on Coupling Constants - NMR Spectroscopy - Organic Chemistry

1. What is a coupling constant in NMR spectroscopy?
Ans. A coupling constant in NMR spectroscopy refers to the splitting pattern observed in the NMR spectrum of a molecule. It provides information about the interactions between neighboring atoms in a molecule, specifically the strength and distance of these interactions.
2. How is the coupling constant related to the number of bonds between coupled atoms?
Ans. The coupling constant is related to the number of bonds between coupled atoms in a molecule. It is denoted as J and is measured in Hertz (Hz). One bond coupling (1J) refers to the interaction between directly bonded atoms, two bond coupling (2J) refers to the interaction between atoms separated by one bond, and three bond coupling (3J) refers to the interaction between atoms separated by two bonds.
3. How does the coupling constant vary in 2J coupling?
Ans. In 2J coupling, the coupling constant can vary depending on the dihedral angle between the coupled atoms. When the dihedral angle is 0° or 180°, the coupling constant is typically larger, resulting in a larger splitting pattern in the NMR spectrum. When the dihedral angle is 90° or 270°, the coupling constant is typically smaller, resulting in a smaller splitting pattern.
4. What is the coupling constant of cis/trans alkenes?
Ans. The coupling constant of cis/trans alkenes is typically large, ranging from 10-20 Hz. This is because the protons on the double bond are usually in a cis or trans configuration, resulting in a strong coupling between them. The coupling constant can provide information about the stereochemistry of the alkene.
5. What is the coupling constant of cyclohexane systems?
Ans. The coupling constant of cyclohexane systems is typically small, ranging from 0-3 Hz. This is because the protons in cyclohexane are usually in a chair conformation, resulting in a weak coupling between them. The coupling constant can provide information about the conformational dynamics of cyclohexane.
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