周期性控制液态磁共振自旋湍流的研究

摘要/Abstract

摘要：

辐射阻尼和远程偶极场联合作用导致的混沌自旋动态能够产生常见于高场梯度磁共振实验中不可再现的实验结果，且该现象较先前所认为的更为常见. 该文发展了一种基于射频微扰的周期性控制方法，以降低Lyapunov指数并抑制在波谱中的不稳定测量结果. 同时讨论了周期性控制的设计原则及如何应用在诸多脉冲序列中，用以抑制自旋湍流.

关键词: 暂态性自旋湍流, 辐射阻尼, 远程偶极场, 混沌控制, 信号放大

Abstract:

Chaotic spin dynamics arising from the joint action of radiation damping and the distant dipolar field are shown to generate irreproducible measurements in popular high-field gradient magnetic resonance experiments, a phenomenon more general than previously thought. A periodic control scheme based on radio-frequency perturbations is developed that decreases the leading Lyapunov exponent and reduces observed fluctuations to within intrinsic spectrometer instability. General guidelines for designing and integrating such schemes into existing pulse sequences to suppress spin chaos are discussed.

Key words: transient spin chaos, radiation damping, distant dipolar field, chaos control, signal amplification

中图分类号:

O482.53

Susie Y. HUANG, Jamie D. WALLS, 林永雅. 周期性控制液态磁共振自旋湍流的研究[J]. 波谱学杂志, 2010, 27(3): 425-435.

Susie Y. HUANG, Jamie D. WALLS, LIN Yung-Ya. Periodic Control of Spin Turbulence in Solution Magnetic Resonance[J]. Chinese Journal of Magnetic Resonance, 2010, 27(3): 425-435.

参考文献

[1] Lin Y Y, Lisitza N, Ahn S, et al. Resurrection of crushed magnetization and chaotic dynamics in solution NMR spectroscopy[J]. Science, 2000, 290: 118-121.
[2] Jeener J. Dynamical instabilities in liquid nuclear magnetic resonance experiments with large nuclear magnetization, with and without pulsed field gradients[J]. J Chem Phys, 2002, 116: 8 439-8 446.
[3] Huang S Y, Lin Y Y, Lisitza N, et al. Signal interferences from turbulent spin dynamics in solution nuclear magnetic resonance spectroscopy[J]. J Chem Phys 2002, 116: 10 325-10 337.
[4] Huang S Y, Walls J D, Wang Y, et al. Signal irreproducibility in high-field solution magnetic resonance experiments caused by spin turbulence[J]. J Chem Phys, 2004, 121: 6 105-6 109. 
[5] Huang S Y, Walls J D, Liong M, et al. in Proceedings of the International Society for Magnetic Resonance in Medicine[C]. Kyoto, May 2004.
[6] Bloembergen N, Pound R V. Radiation damping in magnetic resonance experiments[J]. Phys Rev, 1954, 95: 8-12.
[7] Sodickson A, Maas W E, Cory D G. The initiation of radiation damping by noise[J]. J Magn Reson Ser B, 1996, 110: 298-303.
[8] Augustine M P, Bush S D, Hahn E L. Noise triggering of radiation damping from the inverted state[J]. Chem Phys Lett, 2000, 322: 111-118.
[9] Deville G, Bernier M, Delrieux J M. NMR multiple echoes observed in solid He-3[J]. Phys Rev B, 1979, 19:5 666-5 688.
[10] Bowtell R, Bowley R M, Glover P. Multiple spin echoes in liquids in a high magnetic-field[J]. J Magn Reson, 1990, 88: 643-651.
[11] Warren W S, Richter W. Generation of impossible cross-peaks between bulk water and biomolecules in solution NMR[J]. Science 1993, 262: 2 005-2 009.
[12] Lee S, Richter W, Vathyam S. Quantum treatment of the effects of dipole-dipole interactions in liquid nuclear magnetic resonance\[J\]. J Chem Phys, 1996, 105: 874-900.
[13] Candela D, Hayden M E, Nacher P J. Steady-state production of high nuclear-polarization in He-3-He-4- mixtures[J]. Phys Rev Lett, 1994, 73: 2 587-2 590.
[14] Jeener J. Dynamical effects of the dipolar field inhomogeneities in high-resolution NMR: Spectral clustering and instabilities[J]. Phys Rev Lett, 1999, 82: 1 772-1 775.
[15] Walls J D, Phoa F, Lin Y Y. Spin dynamics at very high spin polarization[J]. Physical Review B, 2004, 70: 174 410.
[16] Sprott J C. Chaos and Time-Series Analysis\[M\]. Oxford: Oxford University Press, 2003.
[17] Lin Y Y. \[D\]. University of California at Berkeley, 1998.
[18] Gueron M, Plateau P, Decorps M. Solvent signal suppression in NMR[J]. Prog NMR Spectrosc, 1991, 23: 135-209.
[19] Cho H M, Tycko R, Pines A. Iterative maps for bistable excitation of 2-level systems[J]. Phys Rev Lett 1986, 56: 1 905-1 908.
[20] Shaka A J, Lee C J, Pines A. Iterative schemes for bilinear operators-application to spin decoupling[J]. J Magn Reson, 1988, 77: 274-293.
[21] Ernst R R, Bodenhausen G, Wokaun A. Principles of nuclear magnetic resonance in one and two dimensions[M]. New York: Oxford University Press, 1990.
[22] Abragam A. Principles of Nuclear Magnetism[M]. New York: Oxford University Press, 1961.
[23] Stejskal E O, Tanner J E. Spin diffusion measurements: spin echoes in the presence of a time-dependent field gradient[J]. J Chem Phys, 1965, 42: 288-295.
[24] Tanner J E. Use of stimulated echo in NMR-diffusion studies[J]. J Chem Phys, 1970, 52: 2 523-2 528.
[25] Broekaert P, Jeener J. Suppression of radiation damping in NMR in liquids by active electronic feedback[J]. J Magn Reson Ser. A, 1995, 113: 60-64.
[26] Abergel D, Louis-Joseph A, Lallemand J Y. Amplification of radiation damping in a 600-MHz NMR spectrometer: application to the study of water-protein interactions[J]. J Biomol NMR, 1996, 8: 15-22.
[27] Lin Y Y, Ahn S, Murali N, Warren W S. High-resolution, >1 GHz NMR in unstable magnetic fields[J]. Phys Rev Lett, 2000, 85: 3 732-3 735.
[28] Bowtell R. Indirect detection via the dipolar demagnetizing field[J]. J Magn Reson, 1992, 100: 1-17.