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¹H NMR of Conformationally Flexible Molecules: Temporal Resolution00:52

¹H NMR of Conformationally Flexible Molecules: Temporal Resolution

913
At room temperature, the chair conformer of cyclohexane undergoes rapid ring flipping between two equivalent chair conformers at a rate of approximately 105 times per second. These two chair conformers are in equilibrium. The rapid ring flipping results in the interconversion of the axial proton to an equatorial proton and an equatorial to the axial proton. Such interconversions are too rapid and cannot be detected on the NMR timescale. Hence, the NMR spectrometer cannot distinguish between the...
913
[3,3] Sigmatropic Rearrangement of 1,5-Dienes: Cope Rearrangement01:21

[3,3] Sigmatropic Rearrangement of 1,5-Dienes: Cope Rearrangement

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The Cope rearrangement is classified as a [3,3] sigmatropic shift in 1,5-dienes, leading to a more stable, isomeric 1,5-diene. The reaction involves a concerted movement of six electrons, four from two π bonds and two from a σ bond, via an energetically favorable chair-like transition state.
2.8K
¹H NMR of Conformationally Flexible Molecules: Variable-Temperature NMR01:15

¹H NMR of Conformationally Flexible Molecules: Variable-Temperature NMR

1.2K
The axial and equatorial protons in cyclohexane can be distinguished by performing a variable-temperature NMR experiment. In this process, except for one proton, the remaining eleven protons are replaced by deuterium. The deuterium substitution avoids the possible peak splitting caused by the spin-spin coupling between the adjacent protons. The remaining proton flips between the axial and equatorial positions.
1.2K
¹H NMR: Complex Splitting01:13

¹H NMR: Complex Splitting

1.3K
A proton M that is coupled to a proton X results in doublet signals for M. However, NMR-active nuclei can be simultaneously coupled to more than one nonequivalent nucleus. When M is coupled to a second proton A, such as in styrene oxide, each peak in the doublet is split into another doublet.
Splitting diagrams or splitting tree diagrams are routinely used to depict such complex couplings. While drawing splitting diagrams, the splitting with the larger coupling constant is usually applied...
1.3K
Chirality at Nitrogen, Phosphorus, and Sulfur02:30

Chirality at Nitrogen, Phosphorus, and Sulfur

5.9K
Chirality is most prevalent in carbon-based tetrahedral compounds, but this important facet of molecular symmetry extends to sp3-hybridized nitrogen, phosphorus and sulfur centers, including trivalent molecules with lone pairs. Here, the lone pair behaves as a functional group in addition to the other three substituents to form an analogous tetrahedral center that can be chiral.
A consequence of chirality is the need for enantiomeric resolution. While this is theoretically possible for all...
5.9K
IR Spectrum Peak Splitting: Symmetric vs Asymmetric Vibrations01:08

IR Spectrum Peak Splitting: Symmetric vs Asymmetric Vibrations

1.2K
Identical bonds within a polyatomic group can stretch symmetrically (in-phase) or asymmetrically (out-of-phase). Similar to hydrogen bonding, these vibrations also influence the shape of the IR peak. Generally, asymmetric stretching frequencies are higher than symmetric stretching frequencies. For example, primary amines exhibit two distinct IR peaks between 3300–3500 cm−1 corresponding to the symmetric and asymmetric N-H stretching, while secondary amines exhibit a single...
1.2K

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Related Experiment Video

Updated: Sep 1, 2025

Line Shape Analysis of Dynamic NMR Spectra for Characterizing Coordination Sphere Rearrangements at a Chiral Rhenium Polyhydride Complex
10:52

Line Shape Analysis of Dynamic NMR Spectra for Characterizing Coordination Sphere Rearrangements at a Chiral Rhenium Polyhydride Complex

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Line Shape Analysis of Dynamic NMR Spectra for Characterizing Coordination Sphere Rearrangements at a Chiral Rhenium

Sarah M Tadros1, Marina Mansour1, Datta V Naik1

  • 1Department of Chemistry and Physics, Monmouth University.

Journal of Visualized Experiments : Jove
|August 15, 2022
PubMed
Summary

Dynamic nuclear magnetic resonance (NMR) spectroscopy reveals atomic rearrangements in transition metal polyhydride complexes. This study presents a new rhenium complex and uses NMR to analyze its dynamic processes and activation parameters.

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Area of Science:

  • Organometallic Chemistry
  • Inorganic Chemistry
  • Spectroscopy

Background:

  • Dynamic solution nuclear magnetic resonance (NMR) spectroscopy is crucial for understanding atomic rearrangements in transition metal polyhydride complexes.
  • Line shape fitting of NMR spectra provides activation parameters for these dynamic processes.
  • Coupled rearrangements of hydride and phosphorus ligands can be investigated using combined NMR techniques.

Purpose of the Study:

  • To characterize dynamic rearrangements in transition metal polyhydride complexes using dynamic NMR spectroscopy.
  • To investigate coupled ligand rearrangements and proton exchange processes.
  • To prepare and analyze a new rhenium complex exhibiting multiple dynamic processes.

Main Methods:

  • Dynamic 31P-{1H} NMR spectroscopy of metal-bound phosphorus.
  • Dynamic 1H-{31P} NMR spectroscopy of hydride ligands.
  • Line shape fitting analysis of NMR spectra.
  • Application of the Eyring equation for activation parameter estimation.

Main Results:

  • A new complex, ReH5(PPh3)2(sec-butyl amine), was synthesized and studied.
  • Dynamic NMR spectra revealed coupled rearrangements of phosphorus and hydride ligands.
  • Proton exchange with solvent molecules was identified as a dynamic process.
  • Activation parameters for identified dynamic processes were estimated.

Conclusions:

  • Dynamic NMR spectroscopy is effective for characterizing complex ligand rearrangements in transition metal complexes.
  • The study provides insights into the dynamic behavior of a novel rhenium polyhydride complex.
  • Activation parameters derived from line shape fitting offer quantitative data on dynamic processes.