Multiple echoes due to distant dipolar fields in NMR of hyperpolarized noble gas solutions

Morgan, Steven W.; Baudin, Emmanuel; Huber, Gaspard; Berthault, Patrick; Tastevin, Geneviève; Goldman, M.; Nacher, Pierre-Jean; Desvaux, Hervé

doi:10.1140/epjd/e2012-30470-0

Cited by 3 publications

(1 citation statement)

References 56 publications

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“…We use inductive FB to study the influence of distant dipolar fields (DDF) on NMR dynamics in highly polarised liquids [35,36,37] and in particular the complex interplay between RD and DDF which results for instance in multiple maser emissions [38]. In our low temperature experiments, the PU coil was a pair of saddle shaped windings connected in series, 3.4 cm long and 1.7 cm in diameter, with 30 turns each of 60-µm-diameter enamelled copper wire (L = 0.14 mH).…”

Section: Control Of Radiation Dampingmentioning

confidence: 99%

Signal feedback applications in low-field NMR and MRI

Kuzmin

Nacher

2020

Journal of Magnetic Resonance

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Tuned pickup coils with high quality factors Q are used in NMR and MRI for high-sensitivity and lownoise detection. However, large Q-factors introduce bandwidth issues at low frequency and the associated enhanced currents may cause significant radiation damping effects, especially with hyperpolarised samples. Signal feedback can be used to actively control these currents and adjust the detection bandwidth without resistive losses. Capacitive and inductive coupling methods are compared using detailed models and the operating conditions for efficient feedback with negligible noise penalty are discussed. Several high-impedance commercial preamplifiers have been found to affect the resonance characteristics of tuned coils in a gain-dependent way, or could not be used in low-frequency NMR because of oscillations at large positive gain. This is attributed to an undocumented internal feedback, and could be neutralised using external feedback. The implementation of an inductive coupling scheme to feed a suitably amplified phase-adjusted signal back into the PU coils of low-field NMR systems is described, and three experimental applications are reported. One system is used for NMR studies of distant dipolar field effects in highly polarized liquid 3 He without or with radiation damping. The moderate intrinsic Q-factor (≈7) could be reduced (down to 1) or increased (up to 100) to control transient maser oscillations. Another system was used for MRI of water samples around 2 mT with Q ≈190 Litz-wire detection coils. The detection bandwidth was increased by actively reducing the Q-factor to obtain uniform sensitivities in images and avoid artifacts introduced by intensity corrections. Finally, parallel acquisition in MRI was performed using two separately tuned detection coils placed above and below the sample. They were actively decoupled using two feedback systems. For an imaging field of view smaller than the sample, artifact-free unfolded images demonstrate the efficiency of this active coil decoupling scheme.

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Section: Control Of Radiation Dampingmentioning

confidence: 99%

Signal feedback applications in low-field NMR and MRI

Kuzmin

Nacher

2020

Journal of Magnetic Resonance

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Nonlinear Effects in NMR

Bechmann

Müller

2017

Annual Reports on NMR Spectroscopy

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Collective effects due to dipolar fields as the origin of the extremely random behavior in hyperpolarized NMR maser: A theoretical and numerical study

Henner

Desvaux

Belozerova

et al. 2013

The Journal of Chemical Physics

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Numerical simulations based on microscopic approach are used to explore the spin dynamics encountered in the recently reported hyperpolarized (129)Xe NMR maser [D. J. Y. Marion, G. Huber, P. Berthault, and H. Desvaux, ChemPhysChem 9, 1395-1401 (2008)] where series of amplitude modulated rf emissions are observed. The integration of the dynamic features of the electronic detection circuit in the present simulations, based on non-linear Maxwell-Bloch differential equations with dipole-dipole interactions, allows us to prove that the experimentally observed extremely random amplitude modulations crucially require the long-distance dipolar couplings between the nuclear spins with the feedback field acting as an amplifier. The massive dipolar couplings act, when the magnetization is largely tilted off the longitudinal axis, as an apparent transverse self-relaxation mechanism which destroys coherence. This, in particular, explains why the final magnetization after emissions can still be opposite to the magnetic field direction, i.e., being in an unstable state.

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Multiple echoes due to distant dipolar fields in NMR of hyperpolarized noble gas solutions

Cited by 3 publications

References 56 publications

Signal feedback applications in low-field NMR and MRI

Signal feedback applications in low-field NMR and MRI

Nonlinear Effects in NMR

Collective effects due to dipolar fields as the origin of the extremely random behavior in hyperpolarized NMR maser: A theoretical and numerical study

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