Reduction of the Spin–Phonon Coupling of Quadrupole Nuclei in NaF Crystals under Magnetic Saturation

IF 0.9 4区 物理与天体物理 Q4 ACOUSTICS Acoustical Physics Pub Date : 2024-02-28 DOI:10.1134/S1063771023601103
V. M. Mikushev, A. M. Rochev, E. V. Charnaya
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Abstract

The rate of nuclear spin-lattice relaxation is determined by the efficiency of interaction between thermal phonons and nuclear spins. The results on reducing the efficiency of spin–phonon coupling by suppressing the contribution from paramagnetic centers to quadrupole nucleus relaxation are presented. The suppression has been performed by continuous magnetic action at the Larmor frequency. It is shown that, as in the presence of an acoustic field, the rate of spin-lattice relaxation of 23Na nuclei in a sodium fluoride crystal at magnetic saturation of the NMR signal does not change in the region of a negative average spin temperature. In the region of positive spin temperature, the rate of relaxation of 23Na spins significantly decreases and nuclear magnetization recovery with time is described by the sum of two exponentials. The contribution from nuclear spins with a lower efficiency of spin–phonon coupling, corresponding to the exponential with a long relaxation time, increases with increasing saturating field intensity. It is demonstrated that the efficiency of spin–phonon coupling for 19F nuclei, which do not have the quadrupole moment, does not change under the saturation conditions. The results obtained can be used for analyzing the structure of real crystals.

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磁饱和状态下 NaF 晶体中四极核的自旋-虹耦合降低
摘要 核自旋-晶格弛豫的速率取决于热声子与核自旋之间相互作用的效率。本文介绍了通过抑制顺磁中心对四极核弛豫的贡献来降低自旋-声子耦合效率的结果。这种抑制是通过拉莫尔频率的连续磁作用实现的。结果表明,与声场存在时一样,在负平均自旋温度区域,氟化钠晶体中 23Na 核在核磁共振信号磁饱和时的自旋晶格弛豫速率不会改变。在正自旋温度区域,23Na 核自旋的弛豫速率显著降低,核磁化随时间的恢复用两个指数之和来描述。自旋-声子耦合效率较低的核自旋的贡献(对应于弛豫时间较长的指数)随着饱和磁场强度的增加而增加。研究表明,不具有四极矩的 19F 核的自旋-声子耦合效率在饱和条件下没有变化。所得结果可用于分析实际晶体的结构。
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来源期刊
Acoustical Physics
Acoustical Physics 物理-声学
CiteScore
1.60
自引率
50.00%
发文量
58
审稿时长
3.5 months
期刊介绍: Acoustical Physics is an international peer reviewed journal published with the participation of the Russian Academy of Sciences. It covers theoretical and experimental aspects of basic and applied acoustics: classical problems of linear acoustics and wave theory; nonlinear acoustics; physical acoustics; ocean acoustics and hydroacoustics; atmospheric and aeroacoustics; acoustics of structurally inhomogeneous solids; geological acoustics; acoustical ecology, noise and vibration; chamber acoustics, musical acoustics; acoustic signals processing, computer simulations; acoustics of living systems, biomedical acoustics; physical principles of engineering acoustics. The journal publishes critical reviews, original articles, short communications, and letters to the editor. It covers theoretical and experimental aspects of basic and applied acoustics. The journal welcomes manuscripts from all countries in the English or Russian language.
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