Relaxation of Multiple-Quantum Coherences in Dipolar Coupled 1H Spin Pairs in Gypsum

IF 0.48 Q4 Physics and Astronomy
E. B. Fel’dman, E. I. Kuznetsova, A. V. Fedorova, K. V. Panicheva, S. G. Vasil’ev, A. I. Zenchuk
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Abstract

The evolution and relaxation of MQ NMR coherences on the preparation period were investigated experimentally on a single crystal of gypsum, CaSO4·2H2O. The theory describing the dynamics of MQ coherences on the preparation period of MQ experiment for a pair of spins was developed based on the Lindblad master equation. This theory predicts the appearance of MQ coherences of only zeroth and second orders, oscillatory exchange of their intensities and exponential decay with increasing of the preparation time. The proposed theory describes the experimental data well. It is shown that the frequency of oscillations depends on the orientation of the crystal in the external magnetic field and determined by the dipolar coupling between protons of the water molecules contained in the gypsum crystal. The relaxation time of MQ coherences of zeroth and second orders, Tr = 150 ± 15 μs, were independent of the crystal orientation, which suggest a common source of relaxation due to the dipole-dipole interactions with protons surrounding water molecule.

Abstract Image

Abstract Image

石膏中双极性耦合 1H 自旋对中的多量子相干弛豫
摘要 在石膏(CaSO4-2H2O)单晶体上对 MQ NMR 相干性在准备期的演变和弛豫进行了实验研究。在林德布拉德主方程的基础上,建立了描述一对自旋 MQ 实验准备期 MQ 相干性动态的理论。该理论预测了 MQ 相干只出现零阶和二阶、其强度的振荡交换以及随着制备时间的增加而出现的指数衰减。所提出的理论很好地描述了实验数据。研究表明,振荡频率取决于晶体在外部磁场中的取向,并由石膏晶体中所含水分子质子之间的双极耦合决定。MQ 相干的零阶和二阶弛豫时间(Tr = 150 ± 15 μs)与晶体取向无关,这表明弛豫的共同来源是水分子周围质子的偶极-偶极相互作用。
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来源期刊
Bulletin of the Russian Academy of Sciences: Physics
Bulletin of the Russian Academy of Sciences: Physics Physics and Astronomy-Physics and Astronomy (all)
CiteScore
0.90
自引率
0.00%
发文量
251
期刊介绍: Bulletin of the Russian Academy of Sciences: Physics is an international peer reviewed journal published with the participation of the Russian Academy of Sciences. It presents full-text articles (regular,  letters  to  the editor, reviews) with the most recent results in miscellaneous fields of physics and astronomy: nuclear physics, cosmic rays, condensed matter physics, plasma physics, optics and photonics, nanotechnologies, solar and astrophysics, physical applications in material sciences, life sciences, etc. Bulletin of the Russian Academy of Sciences: Physics  focuses on the most relevant multidisciplinary topics in natural sciences, both fundamental and applied. Manuscripts can be submitted in Russian and English languages and are subject to peer review. Accepted articles are usually combined in thematic issues on certain topics according to the journal editorial policy. Authors featured in the journal represent renowned scientific laboratories and institutes from different countries, including large international collaborations. There are globally recognized researchers among the authors: Nobel laureates and recipients of other awards, and members of national academies of sciences and international scientific societies.
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