부산대학교 도서관

In magnetic resonance, the bulk magnetization of a sample that is being measured is typically defined as a quantity proportional to spin polarization. The fact that all spins of the same type contribute equally to measurable signals is considered obvious. By focusing on nuclear spin ensembles, we prove the high-field theorem for a general case of spin-I: grouping of spins in molecules does not affect the total measurable NMR signal given thermal equilibrium at high field ($\hbar \gamma B_0 \gg |H_{int}|$, where $|H_{int}|$ is the characteristic amplitude of internal spin-spin interactions). We demonstrate this first by analyzing equations for spin magnetization and then for a general case using the density matrix formalism. We exemplify the theorem implications by predicting NMR signal intensities for ensembles of molecules containing single, two, and three spins. The theorem is not applied in more intricate situations, such as zero- to ultralow-field conditions and far from thermodynamic equilibrium. Considering the populations of rotation levels, the thermal equilibrium polarization at HF and low temperature for H2 gas illustrate one of the intricate cases.
Comment: 26 pages, 6 figures, and 5 appendices