DIRECT MEASUREMENT OF TRANSVERSE RELAXATION TIME OF INTERMOLECULAR MULTIPLE QUANTUM COHERENCES IN NMR

doi:10.1088/1009-1963/10/6/318

Abstract

Abstract A one-dimensional NMR method is presented for measuring the transverse relaxation time, T_2,n, of intermolecular multiple quantum coherences (IMQCs) of coherence order n in highly polarized spin systems. The pulse sequence proposed in this paper effectively suppresses the effects of radiation damping, molecular diffusion, inhomogeneity of magnetic field, and variations of dipolar correlation distance, all of which may affect quantitation of T_2,n. This pulse sequence can be used to measure not only IMQC transverse relaxation time T_2,n(n>1) quickly and directly, but also the conventional transverse relaxation time. Experimental results demonstrate that the quantitative relationship between T_2,n(n≥1) and T₂ is T_2,n≈T₂/n. These results will be helpful for understanding the fundamental properties and mechanisms of IMQCs.

Keywords: nuclear magnetic resonance intermolecular multiple quantum coherences transverse relaxation time pulsed field gradient

Received: 09 November 2000
Revised: 26 February 2001
Accepted manuscript online:

PACS:

33.25.+k

(Nuclear resonance and relaxation)

Fund: Project supported by the National Natural Science Foundation of China (Grant Nos.10005006 and 19975038) and by the National Institute of Health(NIH) of United States (Grant No. NS32024).

Cite this article:

Zheng Shao-kuan (郑绍宽), Chen Zhong (陈忠), Chen Zhi-wei (陈志伟), Zhong Jian-hui (钟健晖) DIRECT MEASUREMENT OF TRANSVERSE RELAXATION TIME OF INTERMOLECULAR MULTIPLE QUANTUM COHERENCES IN NMR 2001 Chinese Physics 10 558

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DIRECT MEASUREMENT OF TRANSVERSE RELAXATION TIME OF INTERMOLECULAR MULTIPLE QUANTUM COHERENCES IN NMR

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