Provides a comprehensive overview of spin-spin couplings in nuclear magnetic resonance, including multiplet patterns and their effect on NMR spectra.
Explores the quantum principles behind Pulsed NMR Spectroscopy, including Zeeman interaction and spin manipulation through radiofrequency irradiation.
Introduces the fundamentals of spin relaxation in magnetic resonance, covering spin-lattice and spin-spin relaxation, and rotational motion in liquids.
Explores the Nuclear Overhauser effect in magnetic resonance and its impact on spin relaxation and enhancement.
Explores spin-spin couplings in NMR, covering equivalent nuclei, molecular symmetry, ³1P NMR spectra, and strong coupling effects.
Explores chemical shifts in NMR, covering local contributions, shielding effects, aromatic compounds, H-bonding impacts, and electron interactions.
Introduces Dynamic Nuclear Polarization in magnetic resonance, emphasizing efficient nuclear spin diffusion and the impact of electron concentration.
Explores nuclear magnetic resonance, MRI principles, pulse sequences, image reconstruction, safety considerations, and volume normalization in brain imaging.
Explores chemical exchange effects in NMR, broadening NMR lines and providing insights into chemical reactions and molecular rearrangements.
