Isotopic shift

The isotopic shift (also called isotope shift) is the shift in various forms of spectroscopy that occurs when one nuclear isotope is replaced by another.

Atomic spectra

If atomic spectra also have hyperfine structure the shift refers to the center of gravity of the spectra. There are two effects which contribute to this shift:

The mass difference. This difference induces a change in the reduced electronic mass. This purely kinematical effect, studied theoretically by Hughes and Eckart^[1] is important for light elements.
The volume difference. This difference induces a change in the electric charge distribution of the nucleus. This effect is important in heavy elements and its first theory was formulated by Pauli and Peierls.^[2]^[3]^[4]

NMR spectroscopy

In NMR spectroscopy, Isotopic effects on chemical shifts are typically small, far less than1 ppm the typical unit for measuring shifts. The ¹
H NMR signals for ¹
H
₂ and ¹
H²
H ("HD") are readily distinguished in terms of their chemical shifts. The asymmetry of the signal for the "protio" impurity in CD
₂Cl
₂ arises from the differing chemical shifts of CDHCl
₂ and CH
₂Cl
₂.

H NMR spectrum of a solution of HD (labeled with red bars) and H₂ (blue bar). The 1:1:1 triplet arises from the coupling of the ¹H nucleus (I = 1/2) to the ²H nucleus ( I = 1).

Vibrational spectra

Isotopic shifts are best known and most widely used in vibration spectroscopy where the shifts are large, being proportional to the ratio of the square root of the isotopic masses. In the case of hydrogen, the "H-D shift" is (1/2)^1/2 or 1/1.41. Thus, the (totally symmetric) C-H vibration for CH
₄ and CD
₄ occur at 2917 cm⁻¹ and 2109 cm⁻¹, respectively.^[5] This shift reflects the differing Reduced mass for the affected bonds.

References

↑ Hughes, D. J.; Eckart, C. (1930). "The Effect of the Motion of the Nucleus on the Spectra of Li I and Li II". Phys. Rev. 36: 694–698. Bibcode:1930PhRv...36..694H. doi:10.1103/PhysRev.36.694.
↑ W. Pauli, R. E. Peierls, Phys. Z. 32 (1931) 670
↑ Brix, P.; Kopfermann, H. (1951). "Neuere Ergebnisse zum Isotopieverschiebungseffekt in den Atomspektren". Festschrift zur Feier des Zweihundertjährigen Bestehens der Akademie der Wissenschaften in Göttingen. Springer. pp. 17–49. doi:10.1007/978-3-642-86703-3_2. ISBN 978-3-540-01540-6.
↑ Kopfermann, H. (1958). Nuclear Moments. Academic Press.
↑ Takehiko Shimanouchi (1972). "Tables of Molecular Vibrational Frequencies Consolidated" (PDF). National Bureau of Standards. NSRDS-NBS-39.

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[1] Hughes, D. J.; Eckart, C. (1930). "The Effect of the Motion of the Nucleus on the Spectra of Li I and Li II". Phys. Rev. 36: 694–698. Bibcode:1930PhRv...36..694H. doi:10.1103/PhysRev.36.694.

[2] W. Pauli, R. E. Peierls, Phys. Z. 32 (1931) 670

[3] Brix, P.; Kopfermann, H. (1951). "Neuere Ergebnisse zum Isotopieverschiebungseffekt in den Atomspektren". Festschrift zur Feier des Zweihundertjährigen Bestehens der Akademie der Wissenschaften in Göttingen. Springer. pp. 17–49. doi:10.1007/978-3-642-86703-3_2. ISBN 978-3-540-01540-6.

[4] Kopfermann, H. (1958). Nuclear Moments. Academic Press.

[5] Takehiko Shimanouchi (1972). "Tables of Molecular Vibrational Frequencies Consolidated" (PDF). National Bureau of Standards. NSRDS-NBS-39.

Isotopic shift

Atomic spectra

NMR spectroscopy

Vibrational spectra

See also

References