The Jahn–Teller effect, sometimes also known as Jahn–Teller distortion, describes the geometrical distortion of molecules and ions that is associated with certain electron configurations. This electronic effect is named after Hermann Arthur Jahn and Edward Teller, who proved, using group theory, that orbital nonlinear spatially degenerate molecules cannot be stable. The Jahn–Teller theorem essentially states that any nonlinear molecule with a spatially degenerate electronic ground state will undergo a geometrical distortion that removes that degeneracy, because the distortion lowers the overall energy of the species. For description of another type of geometrical distortion that occurs in crystals with substitutional impurities see article off-center ions.
Transition metal chemistry
The Jahn–Teller effect is most often encountered in octahedral complexes of the transition metals. The phenomenon is very common in six-coordinate copper(II) complexes. The d9 electronic configuration of this ion gives three electrons in the two degenerate eg orbitals, leading to a doubly degenerate electronic ground state. Such complexes distort along one of the molecular fourfold axes (always labelled the z axis), which has the effect of removing the orbital and electronic degeneracies and lowering the overall energy. The distortion normally takes the form of elongating the bonds to the ligands lying along the z axis, but occasionally occurs as a shortening of these bonds instead (the Jahn–Teller theorem does not predict the direction of the distortion, only the presence of an unstable geometry). When such an elongation occurs, the effect is to lower the electrostatic repulsion between the electron-pair on the Lewis basic ligand and any electrons in orbitals with a z component, thus lowering the energy of the complex. If the undistorted complex would be expected to have an inversion centre, this is preserved after the distortion.
In octahedral complexes, the Jahn–Teller effect is most pronounced when an odd number of electrons occupy the eg orbitals. This situation arises in complexes with the configurations d9, low-spin d7 or high-spin d4 complexes, all of which have doubly degenerate ground states. In such compounds the eg orbitals involved in the degeneracy point directly at the ligands, so distortion can result in a large energetic stabilisation. Strictly speaking, the effect also occurs when there is a degeneracy due to the electrons in the t2g orbitals (i.e. configurations such as d1 or d2, both of which are triply degenerate). In such cases, however, the effect is much less noticeable, because there is a much smaller lowering of repulsion on taking ligands further away from the t2g orbitals, which do not point directly at the ligands (see the table below). The same is true in tetrahedral complexes (e.g. manganate: distortion is very subtle because there is less stabilisation to be gained because the ligands are not pointing directly at the orbitals.
The expected effects for octahedral coordination are given in the following table:
|Number of d electrons||1||2||3||4||5||6||7||8||9||10|
w: weak Jahn–Teller effect (t2g orbitals unevenly occupied), s: strong Jahn–Teller effect expected (eg orbitals unevenly occupied), blank: no Jahn–Teller effect expected.
The Jahn–Teller effect is manifested in the UV-VIS absorbance spectra of some compounds, where it often causes splitting of bands. It is readily apparent in the structures of many copper(II) complexes. Additional, detailed information about the anisotropy of such complexes and the nature of the ligand binding can be however obtained from the fine structure of the low-temperature electron spin resonance spectra.
The Jahn–Teller effect is sometimes encountered in organic compounds, as in the case of cyclobutadiene and cyclooctatetraene, although in some cases the pseudo Jahn–Teller effect (also sometimes called the "second order Jahn–Teller effect") is apparently not present in the D4h transition structure. A clear case however is the case of the COT radical anion, wherein the traditional frost circle π MO diagram (image at right) shows clearly a non-equally filled set of degenerate orbitals. This configuration therefore distorts according to the Jahn–Teller effect (see reference for computational detail of distortion specifics).
- Crystal field theory
- Potential energy surface
- Conical intersection
- Avoided crossing
- Vibronic coupling
- Renner-Teller effect
- H. Jahn and E. Teller (1937). "Stability of Polyatomic Molecules in Degenerate Electronic States. I. Orbital Degeneracy". Proceedings of the Royal Society A 161 (905): 220–235. Bibcode:1937RSPSA.161..220J. doi:10.1098/rspa.1937.0142.
- Patrick Frank, Maurizio Benfatto, Robert K. Szilagyi, Paola D'Angelo, Stefano Della Longa, and Keith O. Hodgson "The Solution Structure of [Cu(aq)]2+ and Its Implications for Rack-Induced Bonding in Blue Copper Protein Active Sites" Inorganic Chemistry 2005, vol 44, pp 1922–1933.doi:10.1021/ic0400639
- Shriver, D. F. & Atkins, P. W. (1999). Inorganic Chemistry (3rd ed) pp 235–236. Oxford University Press ISBN 0-19-850330-X.
- Rob Janes and Elaine A. Moore (2004). Metal-ligand bonding. Royal Society of Chemistry. ISBN 0-85404-979-7.
- A simple quantum mechanical model that illustrates the Jahn-Teller effect Peter Senn; J. Chem. Educ., 1992, 69 (10), p 819  doi:10.1021/ed069p819
- Frank-Gerrit Klärner (2001). "About the Antiaromaticity of Planar Cyclooctatetraene". Angewandte Chemie, Int. Ed. Eng. 40 (21): 3977–3981. doi:10.1002/1521-3773(20011105)40:21<3977::AID-ANIE3977>3.0.CO;2-N.
- Michael J. Bearpark; Blancafort, Luis; Robb, Michael (2002). "The pseudo-Jahn–Teller effect: a CASSCF diagnostic". Molecular Physics 100 (11): 1735–1739. Bibcode:2002MolPh.100.1735B. doi:10.1080/00268970110105442.
- Michael J. Bearpark; Kim, Yong Seol (2000). "Observation of Both Jahn–Teller Distorted Forms (b1g and b2g) of the Cyclooctatetraene Anion Radical in a 1,2-Disubstituted System". J. Am. Chem. Soc. 122 (13): 3211–3215. doi:10.1021/ja9943501.
- Crystal-field Theory, Tight-binding Method, and Jahn-Teller Effect in E. Pavarini, E. Koch, F. Anders, and M. Jarrell (eds.): Correlated Electrons: From Models to Materials, Jülich 2012, ISBN 978-3-89336-796-2