Anti-periplanar explained

In organic chemistry, anti-periplanar, or antiperiplanar, describes the bond angle in a molecule. In this conformer, the dihedral angle of the bond and the bond is greater than +150° or less than −150°^[1] (Figures 1 and 2). Anti-periplanar is often used in textbooks to mean strictly anti-coplanar,^[2] with an dihedral angle of 180° (Figure 3). In a Newman projection, the molecule will be in a staggered arrangement with the anti-periplanar functional groups pointing up and down, 180° away from each other (see Figure 4). Figure 5 shows 2-chloro-2,3-dimethylbutane in a sawhorse projection with chlorine and a hydrogen anti-periplanar to each other.

Syn-periplanar or synperiplanar is similar to anti-periplanar. In the syn-periplanar conformer, the A and D are on the same side of the plane of the bond, with the dihedral angle of and between +30° and −30° (see Figure 2).

Molecular orbitals

An important factor in the antiperiplanar conformer is the interaction between molecular orbitals. Anti-periplanar geometry will put a bonding orbital and an anti-bonding orbital approximately parallel to each other, or syn-periplanar. Figure 6 is another representation of 2-chloro-2,3-dimethylbutane (Figure 5), showing the C–H bonding orbital, σ_C–H, and the C–Cl anti-bonding orbital, σ*_C–Cl, syn-periplanar. The parallel orbitals can overlap and become involved in hyperconjugation. If the bonding orbital is an electron donor and the anti-bonding orbital is an electron acceptor, then the bonding orbital will be able to donate electronegativity into the anti-bonding orbital. This filled-to-unfilled donor-acceptor interaction has an overall stabilizing effect on the molecule. However, donation from a bonding orbital into an anti-bonding orbital will also result in the weakening of both of those bonds. In Figure 6, 2-chloro-2,3-dimethylbutane is stabilized through hyperconjugation from electron donation from σ_C-H into σ*_C-Cl, but both C–H and C–Cl bonds are weakened. A molecular orbital diagram shows that the mixing of σ_C–H and σ*_C–Cl in 2-chloro-2,3-dimethylbutane lowers the energy of both the orbitals (Figure 7).

Examples of anti-periplanar geometry in mechanisms

E₂ mechanism

A bimolecular elimination reaction will occur in a molecule where the breaking carbon-hydrogen bond and the leaving group are anti-periplanar^{[3] [4] [5] [6]} (Figure 8). This geometry is preferred because it aligns σ_C-H and σ*_C-X orbitals.^{[7] [8]} Figure 9 shows the σ_C-H orbital and the σ*_C-X orbital parallel to each other, allowing the σ_C-H orbital to donate into the σ*_C-X anti-bonding orbital through hyperconjugation. This serves to weaken C-H and C-X bond, both of which are broken in an E₂ reaction. It also sets up the molecule to more easily move its σ_C-H electrons into a π_C-C orbital (Figure 10).

Pinacol rearrangement

In the pinacol rearrangement, a methyl group is found anti-periplanar to an activated alcohol functional group.^{[9] [10]} This places the σ_C–C orbital of the methyl group parallel with the σ*_C–O orbital of the activated alcohol. Before the activated alcohol leaves as H₂O the methyl bonding orbital donates into the C–O antibonding orbital, weakening both bonds. This hyperconjugation facilitates the 1,2-methyl shift that occurs to remove water. See Figure 11 for the mechanism.

History, etymology, and misuse

The term anti-periplanar was first coined by Klyne and Prelog in their work entitled "Description of steric relationships across single bonds", published in 1960.^[11] ‘Anti’ refers to the two functional groups lying on opposite sides of the plane of the bond. ‘Peri’ comes from the Greek word for ‘near’ and so periplanar means “approximately planar”.^[12] In their article “Periplanar or Coplanar?” Kane and Hersh point out that many organic textbooks use anti-periplanar to mean completely anti-planar, or anti-coplanar, which is technically incorrect.^[13]

Notes and References

1. Book: Eliel. Ernest. Wilen. Samuel. Mander. Lewis. Stereochemistry of Organic Compounds. September 1994. Wiley-Scientific. New York. 978-0-471-01670-0.
2. Kane. Saul. Hersh. William. Periplanar or Coplanar?. Journal of Chemical Education. 1 October 2000. 77. 10. 1366. 10.1021/ed077p1366. 2000JChEd..77.1366K .
3. Book: Wade. Leroy. Organic Chemistry. limited. 6 January 2012. Pearson. 978-0321768414. 267–268. 8th.
4. Book: Carey. Francis. Sundberg. Richard. Advanced Organic Chemistry: Part A: Structure and Mechanisms. limited. 27 May 2008. Springer. 978-0387683461. 558–563. 5th.
5. Deslongchamps. Ghislain. Deslongchamps. Pierre. Bent bonds, the antiperiplanar hypothesis and the theory of resonance. A simple model to understand reactivity in organic chemistry. Organic & Biomolecular Chemistry. 12 May 2011. 9. 15. 5321–5333. 10.1039/C1OB05393K. 21687842.
6. Web site: Hunt. Ian. Spinney. Rick. Chapter 5: Structure and Preparation of Alkenes. Elimination Reactions. 13 March 2017.
7. Book: Anslyn. Eric. Dougherty. Dennis. Modern Physical Organic Chemistry. limited. 15 July 2005. University Science. 978-1891389313. 590–592.
8. Web site: Rzepa. Henry. An orbtial analysis of the stereochemistry of the E2 elimination reaction. 13 March 2017. 2012-02-04.
9. Book: Anslyn. Eric. Dougherty. Dennis. Modern Physical Organic Chemistry. limited. 15 July 2005. University Science. 978-1891389313. 676–677.
10. Book: Carey. Francis. Sundberg. Richard. Advanced Organic Chemistry: Part B: Reactions and Synthesis. limited. 30 December 2010. Springer. 978-0387683546. 883–886. 5th.
11. Klyne. William. Prelog. Vladimir. Description of steric relationships across single bonds. Experientia. 1 December 1960. 16. 12. 521–523. 10.1007/BF02158433. 48829 .
12. Kane. Saul. Hersh. William. Periplanar or Coplanar?. Journal of Chemical Education. 1 October 2000. 77. 10. 1366. 10.1021/ed077p1366. 2000JChEd..77.1366K .
13. Kane. Saul. Hersh. William. Periplanar or Coplanar?. Journal of Chemical Education. 1 October 2000. 77. 10. 1366. 10.1021/ed077p1366. 2000JChEd..77.1366K .