Exact solution of the CPMG pulse sequence with phase variation down the echo train: Application to R sub(2 measurements)

An implicit exact algebraic solution of CPMG experiments is presented and applied to fit experiments. Approximate solutions are also employed to explore oscillations and effective decay rates of CPMG experiments. The simplest algebraic approximate solution has illustrated that measured intensities w...

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Bibliographic Details
Published in:Journal of magnetic resonance (1997) 2011-04, Vol.209 (2), p.183-194
Main Authors: Bain, Alex D, Anand, Christopher Kumar, Nie, Zhenghua
Format: Article
Language:English
Subjects:
Algebra
Approximation
Echo surveys
Exact solutions
Mathematical analysis
Mathematical models
Offsets
Oscillations
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Summary:An implicit exact algebraic solution of CPMG experiments is presented and applied to fit experiments. Approximate solutions are also employed to explore oscillations and effective decay rates of CPMG experiments. The simplest algebraic approximate solution has illustrated that measured intensities will oscillate in the conventional CPMG experiments and that using even echoes can suppress errors of measurements of R sub(2 due to the imperfection of high-power pulses. To deal with low-power pulses with finite width, we adapt the effective field to calculate oscillations. An optimization model with the effective field approximation and dimensionless variables is proposed to quantify oscillations of measured intensities of CPMG experiments of different phases of the [pi] pulses. We show, as was known using other methods, that repeating one group of four pulses with different phases in CPMG experiments, which we call phase variation, but others call phase alternation or phase cycling, can significantly smooth the dependence of measured intensities on frequency offset in the range of +/-[inline image]. In this paper, a second-order expression with respect to the ratio of frequency offset to [pi]-pulse amplitude is developed to describe the effective R) sub(2) of CPMG experiments when using a group phase variation scheme. Experiments demonstrate that (1) the exact calculation of CPMG experiments can remarkably eliminate systematic errors in measured R sub(2s due to the effects of frequency offset, even in the absence of phase variation; (2) CPMG experiments with group phase variation can substantially remove oscillations and effects of the field inhomogeneity; (3) the second-order expression of the effective decay rate with phase variation is able to provide reliable estimates of R) sub(2) when offsets are roughly within+/-[inline image]; and, most significantly, (4) the more sophisticated optimization model using an exact solution of the discretized CPMG experiment extends, to +/-[gamma]B sub(1, the range of offsets for which reliable estimates of R) sub(2) can be obtained when using the preferred phase variation scheme.
ISSN:1090-7807
DOI:10.1016/j.jmr.2011.01.009